Jonathan Ham

A c-Jun dominant negative mutant protects sympathetic neurons against programmed cell death.

Sympathetic neurons depend on nerve growth factor (NGF) for survival and die by apoptosis in its absence. We have investigated the pattern of expression of the Jun and Fos family of transcription factors in dying sympathetic neurons using antibodies specific for each family member. When sympathetic neurons are deprived of NGF, the level of c-Jun protein significantly increases, whereas the levels of the other members of the Jun and Fos family remain relatively constant. c-Jun also becomes more phosphorylated, probably on its amino terminal transactivation domain. When microinjected into sympathetic neurons, an expression vector for a c-Jun dominant negative mutant protects them against NGF withdrawal-induced death, indicating that AP-1 activity is essential for neuronal cell death. Furthermore, overexpression of the full-length c-Jun protein is, in itself, sufficient to induce apoptosis in sympathetic 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.

Role of the Jun Kinase Pathway in the Regulation of c-Jun Expression and Apoptosis in Sympathetic Neurons

When deprived of nerve growth factor (NGF), developing sympathetic neurons die by apoptosis. This death is associated with an increase in the level of c-Jun protein and is blocked by expression of a c-Jun dominant negative mutant. Here we have investigated whether NGF withdrawal activates Jun kinases, a family of stress-activated protein kinases that can stimulate the transcriptional activity of c-Jun by phosphorylating serines 63 and 73 in the transactivation domain and which can activate c-jun gene expression. We found that sympathetic neurons contained high basal levels of Jun kinase activity that increased further after NGF deprivation. In contrast, p38 kinase, another stress-activated protein kinase that can also stimulate c-jun gene expression, was not activated after NGF withdrawal. Consistent with Jun kinase activation, we found using a phospho-c-Jun-specific antibody that c-Jun was phosphorylated on serine 63 after NGF withdrawal. Furthermore, expression of a constitutively active form of MEK kinase 1 (MEKK1), which strongly activates the Jun kinase pathway, increased c-Jun protein levels and c-Jun phosphorylation and induced apoptosis in the presence of NGF. This death could be prevented by co-expression of SEKAL, a dominant negative mutant of SAPK/ERK kinase 1 (SEK1), an activator of Jun kinase that is a target of MEKK1. In contrast, expression of SEKAL alone did not prevent c-Jun expression, increases in c-Jun phosphorylation, or cell death after NGF withdrawal. Thus, activation of Jun kinase and increases in c-Jun phosphorylation and c-Jun protein levels occur at the same time after NGF withdrawal, but c-Jun levels and phosphorylation are regulated by an SEK1-independent pathway.

c-Jun and the transcriptional control of neuronal apoptosis.

There has been considerable interest in the molecular mechanisms of apoptosis in mammalian neurons because this form of neuronal cell death is important for the normal development of the nervous system and because inappropriate neuronal apoptosis may contribute to the pathology of human neurodegenerative diseases. The aim of recent research has been to identify the key components of the cell death machinery in neurons and understand how the cell death programme is regulated by intracellular signalling pathways activated by the binding of neurotrophins or death factors to specific cell surface receptors. The aim of this commentary was to review research that has investigated the role of the Jun N-terminal kinase (JNK)/c-Jun signalling pathway in neuronal apoptosis, focusing in particular on work carried out with developing sympathetic neurons. Experiments with sympathetic neurons cultured in vitro, as well as with cerebellar granule neurons and differentiated PC12 cells, have demonstrated that JNK/c-Jun signalling can promote apoptosis following survival factor withdrawal. In addition, experiments with Jnk(-/-) knockout mice have provided evidence that Jnk3 may be required for apoptosis in the hippocampus in vivo following injection of kainic acid, an excitotoxin, and that Jnk1 and Jnk2 are required for apoptosis in the developing embryonic neural tube. However, in the embryonic forebrain, Jnk1 and Jnk2 have the opposite function and are necessary for the survival of developing cortical neurons. These results suggest that JNKs and c-Jun are important regulators of the cell death programme in the mammalian nervous system, but that their biological effects depend on the neuronal type and stage of development.

Direct inhibition of c‐Jun N‐terminal kinase in sympathetic neurones prevents c‐jun promoter activation and NGF withdrawal‐induced death

c‐Jun N‐terminal kinases (JNKs) regulate gene expression by phosphorylating transcription factors, such as c‐Jun. Studies with Jnk knockout mice suggest that JNK activity may be required for excitotoxin‐induced apoptosis in the adult hippocampus and for apoptosis in the developing embryonic neural tube. Here we investigate the role of JNKs in classical neurotrophin‐regulated developmental neuronal death by using nerve growth factor (NGF)‐dependent sympathetic neurones. In this system, NGF withdrawal leads to an increase in JNK activity, an increase in c‐Jun protein levels and c‐Jun N‐terminal phosphorylation before the cell death commitment point, and c‐Jun activity is required for cell death. To inhibit JNK activity in sympathetic neurones we have used two different JNK inhibitors that act by distinct mechanisms: the compound SB 203580 and the JNK binding domain (JBD) of JNK interacting protein 1 (JIP‐1). We demonstrate that JNK activity is required for c‐Jun phosphorylation, c‐jun promoter activation and NGF withdrawal‐induced apoptosis. We also show that ATF‐2, a c‐Jun dimerization partner that can regulate c‐jun gene expression, is activated following NGF deprivation. Finally, by co‐expressing the JBD and a regulatable c‐Jun dominant negative mutant we demonstrate that JNK and AP‐1 function in the same pro‐apoptotic signalling pathway after NGF withdrawal.

Stress-activated protein kinases are negatively regulated by cell density.

Stimulation by UV irradiation, TNFα, as well as PDGF or EGF activates the JNK/SAPK signalling pathway in mouse fibroblasts. This results in the phosphorylation of the N‐terminal domain of c‐Jun, increasing its transactivation potency. Using an antibody that specifically recognizes c‐Jun phosphorylated at Ser63, we show that culture confluency drastically inhibited c‐Jun N‐terminal phosphorylation due to the inhibition of the JNK/SAPK pathway. Transfection experiments demonstrate that the inhibition occurs at the same level as, or upstream of, the small G‐proteins cdc42 and Rac1. In contrast, the classical MAPK pathway was insensitive to confluency. The inhibition of JNK/SAPK activation depended on the integrity of the actin microfilament network. These results were confirmed and extended in monolayer wounding experiments. After PDGF, EGF or UV stimulation, c‐Jun was predominantly phosphorylated in cells bordering the wound, which are the cells that move to occupy the wounded area. Thus, modulation of the stress‐dependent signal cascade by confluency will restrict c‐Jun N‐terminal phosphorylation in response to mitogenic or chemotactic agents to cells that border a wounded area.

The bovine papillomavirus 1 E2 protein contains two activation domains: one that interacts with TBP and another that functions after TBP binding.

The E2 transactivator of bovine papillomavirus type‐1 is unable to activate minimal promoters in vivo that contain only E2 binding sites and a TATA box. This block can be overcome by over‐expression of human TATA binding protein (TBP) or by the addition of either SP1 binding sites or an initiator element to the promoter, suggesting that the binding of TFIID may normally be a rate‐limiting step for activation by E2. Surprisingly, purified E2 and TBP bind co‐operatively to DNA in vitro when the sites are closely spaced. E2 does not affect the on rate of association but reduces the off rate. The E2 region responsible for this effect is located in the hinge region that links the classic transactivation and DNA binding domains. We demonstrate that the TBP stabilizing domain contributes in vivo to co‐operativity with co‐expressed TBP and to activation of the major late minimal promoter (MLP) containing E2 sites. In contrast, promoters with SP1 sites are activated to wild‐type levels by such a mutant. This promoter specificity is also evident in vitro. A truncated E2 mutant, lacking the classic transactivation domain but containing the TBP stabilizing domain, stimulates transcription of the MLP in vitro, but does not activate promoters with SP1 sites. In conclusion, our results show that the E2 transactivation domain has a modular structure. We have identified one domain which probably acts at an early step in the assembly of the pre‐initiation complex and which is involved in reducing the dissociation rate of bound TBP in vitro. The classic N‐terminal activation domain of E2 might affect one or several step(s) in the assembly of the preinitiation complex occurring after the binding of TFIID.

Cooperativity in vivo between the E2 transactivator and the TATA box binding protein depends on core promoter structure.

The E2 transactivator protein of bovine papillomavirus 1 (BPV‐1) can strongly stimulate complex promoters such as that of the herpes simplex virus thymidine kinase gene but does not efficiently activate minimal promoters that only contain E2 binding sites and a TATA box. Here we show that overexpression of the human, but not yeast, TATA box binding protein (TBP) in transfection experiments overcomes this block and enables E2 to activate a minimal TATA box‐containing promoter. This suggests that recruitment of the TFIID complex to such promoters is normally a rate limiting step for transcriptional activation by E2 in vivo. In contrast, minimal promoters that contain an initiator element in addition to a TATA box are efficiently activated by E2 on its own and this activation is only moderately enhanced by TBP overexpression. In such E2‐responsive promoters the TATA box or initiator can be functionally replaced by SP1 binding sites. Both the initiator binding protein, TFII‐I, and SP1 have been found to interact physically with components of the TFIID complex. Since either TBP overexpression or the presence of an initiator or SP1 binding sites can increase activation by E2, it seems likely that the principal role of the E2 activation domain is to affect a step in the formation of the transcription initiation complex that occurs after TFIID has bound to the promoter. Sequential action of transcription factors, such as TFII‐I, SP1 and E2, may be one type of mechanism underlying the widely observed phenomenon of transcriptional synergy.

Mkp1 Is a c-Jun Target Gene That Antagonizes JNK-Dependent Apoptosis in Sympathetic Neurons

Developing sympathetic neurons depend on NGF for survival. When sympathetic neurons are deprived of NGF in vitro, a well documented series of events, including c-Jun N-terminal kinase (JNK) pathway activation, release of cytochrome c from the mitochondria, and caspase activation, culminates in the death of the neuron by apoptosis within 24–48 h. This process requires de novo gene expression, suggesting that increased expression of specific genes activates the cell death program. Using rat gene microarrays, we found that NGF withdrawal induces the expression of many genes, including mkp1, which encodes a MAPK phosphatase that can dephosphorylate JNKs. The increase in mkp1 mRNA level requires the MLK-JNK-c-Jun pathway, and we show that Mkp1 is an important regulator of JNK-dependent apoptosis in sympathetic neurons. In microinjection experiments, Mkp1 overexpression can inhibit JNK-mediated phosphorylation of c-Jun and protect sympathetic neurons from apoptosis, while Mkp1 knockdown accelerates NGF withdrawal-induced death. Accordingly, the number of superior cervical ganglion (SCG) neurons is reduced in mkp1−/− mice at P1 during the period of developmental sympathetic neuron death. We also show that c-Jun and ATF2 bind to two conserved ATF binding sites in the mkp1 promoter in vitro and in chromatin. Both of these ATF sites contribute to basal promoter activity and are required for mkp1 promoter induction after NGF withdrawal. These results demonstrate that Mkp1 is part of a negative feedback loop induced by the MLK-JNK-c-Jun signaling pathway that modulates JNK activity and the rate of neuronal death in rat sympathetic neurons following NGF withdrawal.

Programmed cell death during neuronal development: the sympathetic neuron model

Developing sympathetic neurons of the superior cervical ganglion are one of the best studied models of neuronal apoptosis. These cells require nerve growth factor (NGF) for survival at the time that they innervate their final target tissues during late embryonic and early postnatal development. In the absence of NGF, developing sympathetic neurons die by apoptosis in a transcription-dependent manner. Molecular studies of sympathetic neuron apoptosis began in the 1980s. We now know that NGF withdrawal activates the mitochondrial (intrinsic) pathway of apoptosis in sympathetic neurons cultured in vitro, and the roles of caspases, Bcl-2 (B-cell CLL/lymphoma 2) family proteins and XIAP (X-linked inhibitor of apoptosis protein) have been extensively studied. Importantly, a considerable amount has also been learned about the intracellular signalling pathways and transcription factors that regulate programmed cell death in sympathetic neurons. In this article, we review the key papers published in the past few years, covering all aspects of apoptosis regulation in sympathetic neurons and focusing, in particular, on how signalling pathways and transcription factors regulate the cell death programme. We make some comparisons with other models of neuronal apoptosis and describe possible future directions for the field.