Neuroprotection by Caffeine and A2AAdenosine Receptor Inactivation in a Model of Parkinson's Disease
Recent epidemiological studies have established an association between the common consumption of coffee or other caffeinated beverages and a reduced risk of developing Parkinson's disease (PD). To explore the possibility that caffeine helps prevent the dopaminergic deficits characteristic of PD, we investigated the effects of caffeine and the adenosine receptor subtypes through which it may act in the 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) neurotoxin model of PD. Caffeine, at doses comparable to those of typical human exposure, attenuated MPTP-induced loss of striatal dopamine and dopamine transporter binding sites. The effects of caffeine were mimicked by several A(2A) antagonists (7-(2-phenylethyl)-5-amino-2-(2-furyl)-pyrazolo-[4,3-e]-1,2,4-triazolo[1,5-c]pyrimidine (SCH 58261), 3,7-dimethyl-1-propargylxanthine, and (E)-1,3-diethyl-8 (KW-6002)-(3,4-dimethoxystyryl)-7-methyl-3,7-dihydro-1H-purine-2,6-dione) (KW-6002) and by genetic inactivation of the A(2A) receptor, but not by A(1) receptor blockade with 8-cyclopentyl-1,3-dipropylxanthine, suggesting that caffeine attenuates MPTP toxicity by A(2A) receptor blockade. These data establish a potential neural basis for the inverse association of caffeine with the development of PD, and they enhance the potential of A(2A) antagonists as a novel treatment for this neurodegenerative disease.
Resistance of α-synuclein null mice to the parkinsonian neurotoxin MPTP
Parkinson's disease (PD) is most commonly a sporadic illness, and is characterized by degeneration of substantia nigra dopamine (DA) neurons and abnormal cytoplasmic aggregates of ␣-synuclein. Rarely, PD may be caused by missense mutations in ␣-synuclein. MPTP, a neurotoxin that inhibits mitochondrial complex I, is a prototype for an environmental cause of PD because it produces a pattern of DA neurodegeneration that closely resembles the neuropathology of PD. Here we show that ␣-synuclein null mice display striking resistance to MPTP-induced degeneration of DA neurons and DA release, and this resistance appears to result from an inability of the toxin to inhibit complex I. Contrary to predictions from in vitro data, this resistance is not due to abnormalities of the DA transporter, which appears to function normally in ␣-synuclein null mice. Our results suggest that some genetic and environmental factors that increase susceptibility to PD may interact with a common molecular pathway, and represent the first demonstration that normal ␣-synuclein function may be important to DA neuron viability.T he concept of genetic predisposition to disease suggests that one's genes influence susceptibility to environmental insult. However, the relationship between genetic and environmental factors is poorly understood; most models of disease focus on single genes or toxins. A major challenge of postgenomic biology will be to link the molecular pathways modified by diseaseassociated alleles to the environmental factors implicated in disease susceptibility.There is increasing evidence for genetic susceptibility to Parkinson's disease (PD) (1-3). Additionally, dysfunction of a common molecular pathway has been implicated in the familial and sporadic forms of PD. Mutations in the gene that encodes ␣-synuclein cause a rare form of dominantly inherited PD, and ␣-synuclein is an abundant protein in Lewy bodies, the proteinaceous neuronal inclusions that are the pathological hallmark of sporadic PD (4-6). The ␣-synuclein pathway is also implicated in an autosomal recessive form of PD caused by mutations in the gene encoding parkin (7,8). Epidemiological and twin studies suggest that environmental factors alter susceptibility to PD (9). The fact that exposure of humans to the environmental toxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) causes a syndrome that mimics the core neurological symptoms and relatively selective dopamine (DA) neuron degeneration of PD lends support to this concept (10, 11).We asked whether a model neurotoxin for an environmental cause of PD might act on a molecular pathway implicated in genetic and sporadic forms of the disease by generating ␣-synuclein null mice, and testing whether they display altered sensitivity to MPTP-induced degeneration of substantia nigra (SN) DA neurons. MethodsAnimal Generation. A 5.7-kb EcoRV mouse ␣-synuclein fragment (Fig. 1A) was used to generate the targeting construct. A DNA fragment containing, in order, LoxP-phosphoglycerate kinaseNeomycin-transcription blocking '...
A key question in understanding mechanisms of neurotransmitter release is whether the fusion pore of a synaptic vesicle regulates the amount of transmitter released during exocytosis. We measured dopamine release from small synaptic vesicles of rat cultured ventral midbrain neurons using carbon fiber amperometry. Our data indicate that small synaptic vesicle fusion pores flicker either once or multiple times in rapid succession, with each flicker releasing approximately 25-30% of vesicular dopamine. The incidence of events with multiple flickers was reciprocally regulated by phorbol esters and staurosporine. Thus, dopamine neurons regulate the amount of neurotransmitter released by small synaptic vesicles by controlling the number of fusion pore flickers per exocytotic event. This mode of exocytosis is a potential mechanism whereby neurons can rapidly reuse vesicles without undergoing the comparatively slow process of recycling.
Fluorescent False Neurotransmitters Visualize Dopamine Release from Individual Presynaptic Terminals
The nervous system transmits signals between neurons via neurotransmitter release during synaptic vesicle fusion. In order to observe neurotransmitter uptake and release from individual presynaptic terminals directly, we designed fluorescent false neurotransmitters as substrates for the synaptic vesicle monoamine transporter. Using these probes to image dopamine release in the striatum, we made several observations pertinent to synaptic plasticity. We found that the fraction of synaptic vesicles releasing neurotransmitter per stimulus was dependent on the stimulus frequency. A kinetically distinct "reserve" synaptic vesicle population was not observed under these experimental conditions. A frequency-dependent heterogeneity of presynaptic terminals was revealed that was dependent in part on D2 dopamine receptors, indicating a mechanism for frequency-dependent coding of presynaptic selection.
Dysregulation of dopamine homeostasis and elevation of the cytosolic level of the transmitter have been suggested to underlie the vulnerability of catecholaminergic neurons in Parkinson's disease. Because several known mutations in ␣-synuclein or overexpression of the wild-type (WT) protein causes familial forms of Parkinson's disease, we investigated possible links between ␣-synuclein pathogenesis and dopamine homeostasis. Chromaffin cells isolated from transgenic mice that overexpress A30P ␣-synuclein displayed significantly increased cytosolic catecholamine levels as measured by intracellular patch electrochemistry, whereas cells overexpressing the WT protein and those from knock-out animals were not different from controls. Likewise, catechol concentrations were higher in L-DOPAtreated PC12 cells overexpressing A30P or A53T compared with those expressing WT ␣-synuclein, although the ability of cells to maintain a low cytosolic dopamine level after L-DOPA challenge was markedly inhibited by either protein. We also found that incubation with low-micromolar concentrations of WT, A30P, or A53T ␣-synuclein inhibited ATP-dependent maintenance of pH gradients in isolated chromaffin vesicles and that the WT protein was significantly less potent in inducing the proton leakage. In summary, we demonstrate that overexpression of different types of ␣-synuclein disrupts vesicular pH and leads to a marked increase in the levels of cytosolic catechol species, an effect that may in turn trigger cellular oxyradical damage. Although multiple molecular mechanisms may be responsible for the perturbation of cytosolic catecholamine homeostasis, this study provides critical evidence about how ␣-synuclein might exert its cytotoxicity and selectively damage catecholaminergic cells.
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