JNK2 and JNK3 combined are essential for apoptosis in dopamine neurons of the substantia nigra, but are not required for axon degeneration.

Activation of c-jun N-terminal kinase (JNK) by the mitogen-activated protein kinase cascade has been shown to play an important role in the death of dopamine neurons of the substantia nigra, one of the principal neuronal populations affected in Parkinson's disease. However, it has remained unknown whether the JNK2 and JNK3 isoforms, either singly or in combination, are essential for apoptotic death, and, if so, the mechanisms involved. In addition, it has been unclear whether they play a role in axonal degeneration of these neurons in disease models. To address these issues we have examined the effect of single and double jnk2 and jnk3 null mutations on apoptosis in a highly destructive neurotoxin model, that induced by intrastriatal 6-hydroxydopamine. We find that homozygous jnk2/3 double null mutations result in a complete abrogation of apoptosis and a prolonged survival of the entire population of dopamine neurons. In spite of this complete protection at the cell soma level, there was no protection of axons. These studies provide a striking demonstration of the distinctiveness of the mechanisms that mediate cell soma and axon degeneration, and they illustrate the need to identify and target pathways of axon degeneration in the development of neuroprotective therapeutics.

CHOP/GADD153 is a mediator of apoptotic death in substantia nigra dopamine neurons in an in vivo neurotoxin model of parkinsonism.

There is increasing evidence that neuron death in neurodegenerative diseases, such as Parkinson's disease, is due to the activation of programmed cell death. However, the upstream mediators of cell death remain largely unknown. One approach to the identification of upstream mediators is to perform gene expression analysis in disease models. Such analyses, performed in tissue culture models induced by neurotoxins, have identified up-regulation of CHOP/GADD153, a transcription factor implicated in apoptosis due to endoplasmic reticulum stress or oxidative injury. To evaluate the disease-related significance of these findings, we have examined the expression of CHOP/GADD153 in neurotoxin models of parkinsonism in living animals. Nuclear expression of CHOP protein is observed in developmental and adult models of dopamine neuron death induced by intrastriatal injection of 6-hydroxydopamine (6OHDA) and in models induced by 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). CHOP is a mediator of neuron death in the adult 60HDA model because a null mutation results in a reduction in apoptosis. In the chronic MPTP model, however, while CHOP is robustly expressed, the null mutation does not protect from the loss of neurons. We conclude that the role of CHOP depends on the nature of the toxic stimulus. For 6OHDA, an oxidative metabolite of dopamine, it is a mediator of apoptotic death.

Mixed lineage kinase-c-jun N-terminal kinase signaling pathway: a new therapeutic target in Parkinson's disease.

There is growing evidence that the molecular pathways of programmed cell death play a role in neurodegenerative disease, including Parkinson's disease, so there has been increased interest in them as therapeutic targets for the development of neuroprotective strategies. One pathway of cell death that has attracted particular attention is the mixed lineage kinase (MLK) -c-jun N-terminal kinase (JNK) signaling cascade, which leads to the phosphorylation and activation of the transcription factor c-jun. There is much evidence, from in vitro and in vivo studies, that this cascade can mediate cell death. In addition, there is evidence that it is operative upstream in the death process. It is possible that abrogation of this pathway may forestall death before irreversible cellular injury. One class of compounds that has shown promise for their ability to block cell death by inhibiting this cascade are the inhibitors of the MLKs, which are upstream in the activation of c-jun. One of these compounds, CEP1347, is now in a Phase II/III clinical trial for neuroprotection in PD. Whether this trial is successful or not, this signaling cascade is likely to be a focus of future therapeutic development. This review, therefore, outlines the principles of signaling within this kinase pathway, and the evidence for its role in cell death. We review the evidence that inhibition of the MLKs can prevent dopamine neuron cell death and the degeneration of their axons. These studies suggest important future directions for the development of therapies that will target this important cell death pathway.

Interrelationships between mu opioid and melanocortin receptors in mediating food intake in rats.

The present study examined the interrelationships between feeding responses produced by mu opioid receptor agonists and melanocortin-3 or 4 (MC-3/4) receptor antagonists. Feeding induced by the mu-sensitive opioid peptide, beta-endorphin (betaEND, 10 microg, i.c.v.) was significantly and dose-dependently reduced by pretreatment with the MC-3/4 receptor agonist, melanotan-II (MTII: 0.01-10 nmol, i.c.v.). Moreover, the selective mu opioid antagonist, beta-funaltrexamine (betaFNA: 2-20 mug, i.c.v.), significantly and dose-dependently reduced feeding and weight gain elicited by the potent MC-3/4 receptor antagonist, SHU-9119 (0.5 nmol, i.c.v.), especially at those intake periods (24-48 h) when SHU-9119 produced maximal ingestive effects. These data extend previous findings demonstrating interactions between opioid and melanocortin receptors in the mediation of food intake.

Pitx3 is required for development of substantia nigra dopaminergic neurons.

Dopaminergic (DA) neurons of substantia nigra in the midbrain control voluntary movement, and their degeneration is the cause of Parkinson's disease. The complete set of genes required to specifically determine the development of midbrain DA subgroups is not known yet. We report here that mice lacking the bicoid-related homeoprotein Pitx3 fail to develop DA neurons of the substantia nigra. Other mesencephalic DA neurons of the ventral tegmental area and retrorubral field are unaltered in their dopamine expression and histological organization. These data suggest that Pitx3-dependent gene expression is specifically required for the differentiation of DA progenitors within the mesencephalic DA system.

Differential dose-dependent effects of central morphine treatment upon food intake in male and female rats receiving neonatal hormone manipulations.

Male rats display significantly greater analgesic responses following morphine than female rats, with neonatal gonadal manipulations reversing the sex-dependent pattern. The present study assessed whether dose-dependent (0.0005-5 microg, icv) effects of morphine-induced feeding were sensitive to sex-dependent and neonatal gonadectomy manipulations. Sex differences in morphine-induced feeding varied as a function of morphine dose with males showing greater increases at low (0.0005 microg) doses, and females showing greater increases at high (5 microg) doses. Neonatal castration, respectively, enhanced and reduced morphine-induced feeding at very low (0.0005 microg) and low (0.005 microg) doses. In contrast, neonatal testosterone administered to females enhanced morphine-induced feeding at higher (0.5-5 microg) doses. These data indicate that sex and neonatal gonadectomy differences in morphine-induced feeding are dependent upon the dose of morphine employed.

Feeding induced by food deprivation is differentially reduced by G-protein alpha-subunit antisense probes in rats.

Antisense oligodeoxynucleotide (AS ODN) probes directed against the alpha-subunit of different G-proteins have been used to differentiate feeding responses in rats elicited by different opioid agonists, including morphine, beta-endorphin and dynorphin. Furthermore, antisense probes directed against G(o)alpha, but not G(s)alpha, G(q)alpha or G(i)alpha, significantly reduced nocturnal feeding in rats. The present study examined whether food intake and weight changes elicited by 24 h of food deprivation were significantly altered by ventricular administration of antisense probes directed against either G(i)alpha(1), G(i)alpha(2), G(i)alpha(3), G(s)alpha, G(o)alpha, G(q)alpha or G(x/z)alpha as well as a control nonsense probe in rats. Deprivation-induced weight loss was significantly enhanced by antisense probes directed against G(s)alpha and G(x/z)alpha, whereas weight recovery 24 h following reintroduction of food was significantly reduced by antisense probes directed against G(i)alpha(2), G(q)alpha and G(o)alpha. Selective antisense probe effects were noted for deprivation-induced intake with G(s)alpha and G(q)alpha probes exerting the greatest reductions, G(x/z)alpha, G(i)alpha(2), and G(i)alpha(3) probes exerting lesser effects, and G(i)alpha(1) and G(o)alpha probes failing to affect deprivation-induced intake. Importantly, the nonsense control probe failed to alter deprivation-induced intake or weight. The reductions in deprivation-induced intake by AS ODN probes directed against G(s)alpha or G(q)alpha were not accompanied by any evidence of a conditioned taste aversion. These data indicate important distinctions between G-protein mediation of different effector signaling pathways mediating feeding responses elicited under natural (e.g. nocturnal feeding) and regulatory challenge (e.g. food deprivation) conditions.

Pharmacological characterization of beta-endorphin- and dynorphin A(1-17)-induced feeding using G-protein alpha-subunit antisense probes in rats.

Antisense (AS) oligodeoxynucleotides targeting G-protein alpha-subunits distinguish feeding responses of morphine and its metabolite, as well as nocturnal and deprivation-induced feeding. The present study examined whether feeding elicited by beta-endorphin (betaEND) or dynorphin A(1-17) was altered by ventricularly-applied G(i)alpha(1), G(i)alpha(2), G(i)alpha(3), G(s)alpha, G(o)alpha, G(q)alpha or G(x/z)alpha AS probes, or a nonsense (NS) control. The betaEND-induced feeding was reduced by the G(i)alpha(1) and G(x/z)alpha AS probes, and increased by G(i)alpha(2) or G(i)alpha(3) AS treatment. Dynorphin-induced feeding was attenuated by G(i)alpha(1) and G(o)alpha AS treatment. Yet, G(s)alpha or G(q)alpha AS and NS treatments failed to alter opioid agonist-induced feeding. These data provide initial characterization of potential effector signaling pathways mediating betaEND and dynorphin-induced feeding.

Dynorphin A(1-17)-induced feeding: pharmacological characterization using selective opioid antagonists and antisense probes in rats.

Ventricular administration of the opioid dynorphin A(1-17) induces feeding in rats. Because its pharmacological characterization has not been fully identified, the present study examined whether a dose-response range of general and selective opioid antagonists as well as antisense oligodeoxynucleotide (AS ODN) opioid probes altered daytime feeding over a 4-h time course elicited by dynorphin. Dynorphin-induced feeding was significantly reduced by a wide range of doses (5-80 nmol i.c.v.) of the selective kappa(1)-opioid antagonist nor-binaltorphamine. Correspondingly, AS ODN probes directed against either exons 1 and 2, but not 3 of the kappa-opioid receptor clone (KOR-1) reduced dynorphin-induced feeding, whereas a missense oligodeoxynucleotide control probe was ineffective. Furthermore, AS ODN probes directed against either exons 1 or 2, but not 3 of the kappa(3)-like opioid receptor clone (KOR-3/ORL-1) also attenuated dynorphin-induced feeding. Although the selective mu-antagonist beta-funaltrexamine (20-80 nmol) reduced dynorphin-induced feeding, an AS ODN probe directed only against exon 1 of the mu-opioid receptor clone was transiently effective. Neither general (naltrexone, 80 nmol) nor delta (naltrindole, 80 nmol)-selective opioid antagonists were particularly effective in reducing dynorphin-induced feeding, and an AS ODN probe targeting the individual exons of the delta-opioid receptor clone failed to significantly reduce dynorphin-induced feeding. These converging antagonist and AS ODN data firmly implicate the kappa(1)-opioid receptor and the KOR-1 and KOR-3/ORL-1 opioid receptor genes in the mediation of dynorphin-induced feeding.