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Histopathological, biochemical and in vivo brain imaging techniques, such as magnetic resonance imaging and transcranial sonography, revealed a consistent increase of substantia nigra (SN) iron in Parkinson’s disease (PD). Increased iron deposits in the SN may have genetic and non-genetic causes. There are several rare movement disorders associated with neurodegeneration, and genetic abnormalities in iron regulation resulting in iron deposition in the brain. Non-genetic causes of increased SN iron may be the result of a disturbed or open blood-brain-barrier, local changes in the normal iron-regulatory systems, intraneuronal transportation of iron from iron-rich area into the SN and release of iron from intracellular iron storage molecules. Major iron stores are ferritin and haemosiderin in glial cells as well as neuromelanin in neurons. Age- and disease dependent overload of iron storage proteins may result in iron release upon reduction. Consequently, the low molecular weight chelatable iron complexes may trigger redox reactions leading to damage of biomolecules. Additionally, upon neurodegeneration there is strong microglial activation which can be another source of high iron concentrations in the brain.

Friedreich ataxia is due to insufficient levels of frataxin, a mitochondrial iron chaperone that shields this metal from reactive oxygen species (ROS) and renders it bioavailable as Fe II. Frataxin participates in the synthesis of iron-sulfur clusters (ISCs), cofactors of several enzymes, including mitochondrial and cytosolic aconitase, complexes I, II and III of the respiratory chain, and ferrochelatase. It also plays a role in the maintenance of ISCs, in particular for mitochondrial aconitase. A role of frataxin in heme synthesis has been postulated, but is controversial. Insufficient frataxin leads to deficit of ISC enzymes and energy deficit. Iron levels increase in mitochondria. Oxidative stress may result from respiratory chain dysfunction and from direct reaction between iron and ROS. Stress pathways are activated that may lead to apoptosis or other forms of cell death. The basis for the selective vulnerability of specific neurons, like sensory neurons, is still unknown.

Study of the nongenetic causes of Parkinson’s disease (PD) was encouraged by discovery of a cluster of parkinsonism produced by neurotoxic pyridine 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) in the 1980s. Since that time, epidemiologic investigations have suggested risk factors, though their results do not establish causality. Pesticide exposure has been associated with increased risk in many studies. Other proposed risks include rural residence and certain occupations. Cigarette smoking, use of coffee/caffeine, and non-steroidal antiinflammatory drugs (NSAIDs) all appear to lower risk of PD, while dietary lipid and milk consumption, high caloric intake, and head trauma may increase risk. The cause of PD is likely multifactorial. Underlying genetic susceptibility and combinations of risk and protective factors likely all contribute. The combined research effort by epidemiologists, geneticists, and basic scientists will be needed to clarify the cause(s) of PD.

An abnormally frequent atypical levodopa-unresponsive, akinetic-rigid syndrome with some similarity to PSP was identified in the Caribbean island Guadeloupe, and was associated with the consumption of plants of the Annonacea family, especially Annona muricata (corossol, soursop) suggesting a possible toxic etiology. Annonaceae contain two groups of potential toxins, alkaloids and acetogenins. Both alkaloids and annonacin, the most abundant acetogenin, were toxic in vitro to dopaminergic and other neurons. However we have focused our work on annonacin for two reasons: (1) annonacin was toxic in nanomolar concentrations, whereas micromolar concentrations of the alkaloids were needed, (2) acetogenins are potent mitochondrial poisons, like other parkinsonism-inducing compounds. We have also shown that high concentrations of annonacin are present in the fruit or aqueous extracts of the leaves of A. muricata , can cross the blood brain barrier since it was detected in brain parenchyma of rats treated chronically with the molecule, and induced neurodegeneration of basal ganglia in these animals, similar to that observed in atypical parkinsonism. These studies reinforce the concept that consumption of Annonaceae may contribute to the pathogenesis of atypical parkinsonism in Guadeloupe.

The ecogenetic theory contends that most cases of Parkinson’s disease (PD) result from the actions of environmental factors in genetically susceptible individuals on a background of normal ageing. This notion is supported by epidemiologic data; family history of PD and exposures to environmental toxins such as pesticides increase risk, while cigarette smoking reduces risk. As a result, polymorphic genes that code for metabolic enzymes have been considered as candidates for conferring differential risk for PD. Given their prominence in xenobiotic metabolism, the cytochrome P450 (CYP) genes have come under great scrutiny. The activity of CYP2D6 is largely determined by genetic variability and common sequence variants exist in human populations that lead to poor metaboliser (PM) phenotypes. These have been extensively studied as genetic risk factors for PD with inconsistent results. However, these studies have disregarded interactive effects (e.g. gene × environment interactions) despite the assertions of the ecogenetic theory. Data from our group and others suggest that the CYP2D6 PM genotype interacts with certain environmental factors such as pesticide exposure and cigarette smoking to confer differential risk for PD. Previous failure to consider such interactions might, in part, explain the inconsistencies observed in the CYP2D6 genetic risk-factor literature. Our data illustrate, using CYP2D6 as an exemplar, that it is crucial to consider both genetic and environmental factors, and their interactions, in any examination of risk factors for PD.

Cytochromes P450 is a family of heme proteins that metabolize xenobiotics including drugs. Unique human brain cytochrome P450 enzymes metabolize xenobiotics including drugs to active/inactive metabolites through biotransformation pathways that are different from the well-characterized ones in liver. We have identified an alternate spliced functional transcript of CYP2D7 containing partial inclusion of intron 6 in human brain but not in liver or kidney from the same individual. Genotyping revealed the presence of the frame-shift mutation 138delT only in those subjects who expressed the brain variant CYP2D7, which metabolizes codeine exclusively to morphine unlike hepatic CYP2D6 that metabolizes codeine to nor codeine and morphine. CYP1A1 bioactivates polycyclic aromatic hydrocarbons to reactive DNA binding metabolites and initiates carcinogenesis. We have identified a unique splice variant of CYP1A1 having deletion of 87 bp of exon 6 which is present in human brain but not in liver of the same individual. We present evidence for the existence of biotransformation pathways in human brain that are dissimilar from known pathways in liver. Identification and characterization of novel CNS-specific P450 enzymes generated by alternate splicing of known genes or as yet unidentified genes may help predict consequences of exposure to xenobiotics including pesticides in the brain.

Elucidation of the biochemical steps leading to the 1-Methyl-4-Phenyl-1,2,3,6-Tetrahydropyridine (MPTP)-induced degeneration of the nigro-striatal dopamine (DA) pathway has provided new clues to the pathophysiology of Parkinson’s Disease (PD). In line with the enhancement of MPTP toxicity by diethyldithiocarbamate (DDC), here we demonstrate how other CYP450 (2E1) inhibitors, such as diallyl sulfide (DAS) or phenylethylisothiocyanate (PIC), also potentiate the selective DA neuron degeneration in C57/bl mice. In order to provide direct evidence for this isozyme involvement, CYP 2E1 knockout mice were challenged with MPTP or the combined treatment. Here we show that these transgenic mice have a low sensitivity to MPTP alone, similarly to the wild type SVI, suggesting that it is likely that transgenic mice compensate for the missing enzyme. However, in these CYP 2E1 knockout mice, DDC pretreatment completely fails to enhance MPTP toxicity; this enhancement is instead regularly present in the SVI control animals. This study indicates that the occurrence of CYP 2E1 in C57/bl mouse brain is relevant for MPTP toxicity, and suggests that this isozyme may have a detoxificant role related to the efflux transporter of the toxin.

Brain expression of cytochromes P450 2B6, 2D6 and 2E1 is higher in smokers, and is induced by nicotine in animals. These enzymes can metabolize many of the neurotoxins associated with Parkinson’s disease. Since smoking is known to be protective against Parkinson’s disease, we hypothesise that nicotine-induced elevation of brain CYPs in smokers may contribute to neuroprotection against Parkinson’s disease. This supports the therapeutic use of nicotine to delay the progress of this disease.

The functional characterization of identified disease genes in monogenic forms of Parkinson’s disease (PD) allows first insights into molecular pathways leading to neurodegeneration and dysfunction of the nigrostriatal system. There is increasing evidence that disturbance of the ubiquitin proteasome pathway is one important feature of this process underscoring the relevance of protein misfolding and accumulation in the neurodegenerative process of PD. Other genes are involved in mitochondrial homeostasis and still others link newly identified signalling pathways to the established paradigm of oxidative stress in PD. Additional factors are posttranslational modifications of key proteins such as phosphorylation. Also, molecular data support the role of altered iron metabolism in PD. Here we describe known genes and novel genetic susceptibility factors and define their role in neurodegeneration.

To date 11 forms of familial Parkinson’s disease (PD) have been mapped to different chromosome loci, of which 6 genes have been identified as the causative genes, i.e., alpha-synuclein ( SNCA ), parkin,UCH-L1, PINK1, DJ-1 , and LRRK2 . For UCH-L1 , additional families with this mutation are necessary before concluding that UCH-L1 is the definite causative gene for PARK5, as only one family so far has been reported. SNCA, UCH-L1 , and LRRK2 mutations cause autosomal dominant PD and the remaining gene mutations autosomal recessive PD. Age of onset tends to be younger in familial PD compared with sporadic PD, particularly so in autosomal recessive PD. Generally familial cases respond to levodopa quite nicely and progression of the disease tends to be slower. It is an interesting question how familial PD-causing proteins are mutually related each other. In this article, we review recent progress in genetics and molecular biology of familial PD.