Autoradiography of l–Methyl–4–phenyl–l,2,3,6–tetrahydropyridine (MPTP): Uptake in the Monoaminergic Pathways and in Melanin Containing Tissues

Lydén, Annika; Bondesson, Ulf; Larsson, Bengt; Lindquist, Nils Gunnar; Olsson, Lars‐Inge

doi:10.1111/j.1600-0773.1985.tb00020.x

Cited by 29 publications

(12 citation statements)

References 19 publications

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“…Although the liver, kidneys, and brain contained the highest levels of radioactivity at the end of the scintigraphic study, a progressive accumulation of radioactivity was observed within the eyes over the course of the imaging study. Accumulation within this organ was evident within 50 min postinjection; such accumulation has been reported by other groups using radiolabeled MPTP in the monkey (Hartvig et al, 1986) and is presumed to reflect high retinal MA0 activity and trapping of metabolites by melanin-containing dopaminergic neurons of the retina (D'Amato et al, 1987;Lyden et al, 1985). In contrast to the rodent heart, which maintains levels of [ 1251]MHTP-derived radioactivity comparable to those of the brain (Efange et al, 1989), very little radioactivity was retained in the monkey heart.…”

Section: Resultssupporting

confidence: 59%

“…However, the selective dopaminergic neurotoxicity of MPTP may be partially explained by the regional distribution of MPP in vivo. Following the administration of radiolabeled MPTP to rodents, high concentrations of radioactivity were found within the caudate-putamen, nucleus accumbens, and locus coeruleus (Lyden et al, 1985;Lyden-Sokolowski et al, 1988). These areas of the brain are known to contain the highest concentrations of catecholamine uptake sites (Javitch et al, 198513).…”

Section: Introductionmentioning

confidence: 99%

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Pargyline‐Sensitive selective accumulation of a radiolabeled MPTP analog in the primate cerebral cortex and basal ganglia

Efange

Kung

Mash

et al. 1990

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The distribution of radioiodinated N-methyl-4-(4-hydroxy-3-iodobenzyl)-1,2,3,6-tetrahydropyridine (MHTP), an analog of the reportedly nontoxic N-methyl-4-benzyl-1,2,3,6-tetrahydropyridine, (4-homo-MPTP), has been studied in the primate. [123I]MHTP-derived radioactivity exhibited a progressive accumulation and prolonged retention within the primate eye. Following iv injection, [123I]MHTP rapidly accumulated within the primate brain and was subsequently oxidized to a radiolabeled metabolite. The half-life of [123I]MHTP-derived radioactivity within the primate brain was 50 min. The highest concentrations of radioactivity were found in the caudate-putamen and the frontal, temporal and cingulate cortices; the substantia nigra and inferior olivary nucleus were labeled with medium intensity. Very low concentrations of radiolabel were detected in the cerebellum and white matter. Selective accumulation of [125I]MHTP-derived radioactivity within these structures was blocked by pretreatment with pargyline, suggesting that monoamine oxidase B is involved in the bioactivation of radioiodinated MHTP.

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Section: Resultssupporting

confidence: 59%

Section: Introductionmentioning

confidence: 99%

Pargyline‐Sensitive selective accumulation of a radiolabeled MPTP analog in the primate cerebral cortex and basal ganglia

Efange

Kung

Mash

et al. 1990

Synapse

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“…The substance was ultimately purified and demonstrated to bind to melanin (25). The substance produces Parkinson-like symptoms in animals but only in those species that contain high levels of neuromelanin in the substantia nigra (26). It also preferentially kills melanoma cells containing high levels of melanins (27).…”

Section: Fifth Blind Person: "I Know What Melanin Does! It Binds To Dmentioning

confidence: 99%

The function of melanin or six blind people examine an elephant

1992

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The pigment melanin is found in all living kingdoms and in many different structures and forms. When its various functions are examined separately, its behaviors seem disparate and conflicting. It has a clear role in camouflage and sexual display. Other major roles are examined critically. It can act as a sun screen but is not a very effective one. It can also scavenge active chemical species, but this, too, is not done very effectively. It produces active radicals that can damage DNA. It binds to drugs in ways that are either beneficial or deleterious. Aside from camouflage, its other roles can be brought together by a unifying hypothesis as first proposed by Proctor and McGinness nearly 20 years ago. Melanin is envisaged as an energy transducer with the properties of an amorphous semiconductor. It can absorb many different types of energy and dissipate them in the form of heat. However, if the energy input is too great, the output can be expressed in the form of activated chemical species that can damage cellular macromolecules resulting in cell death, mutations and cancer. The protective aspect of melanin in dark skin is seen as resulting from its high concentration and its confinement to ellipsoidal and densely packed organelles that can effectively shield the nucleus. In light skin, its radical nature is seen as potentially participating in the carcinogenic process, particularly when overwhelmed by intense episodes of sunburn.

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“…Additionally, decreased concentration of corticotropin-releasing factor, found in PD patients, was also recorded in amygdala and paraventricular nucleus of hypothalamus in MPTP-treated rats (Huang and Lee 1995). Significant loss of DA and 5-hydroxytryptamine (serotonin) was recorded in amygdala along with striatum, (Lyden et al 1985) Altered glucose metabolism in spinal cord (Schwartzman and Alexander 1985) Presence of MPTP metabolizing system in spinal cord (Samantaray et al 2008b) Neurodegeneration in cervical and lumbar spinal cord neurons (Samantaray et al 2008a,b) Upregulation of calpain expression and activity in spinal neural cells (Ray et al 2000;Chera et al 2002Chera et al , 2004 Acupuncture at GB34 and LR3 acupoints altered gene expression in cervical spinal cord (Choi et al 2011) Alpha-synuclein pathology and astrogliosis with progressive loss of locomotor function (Neumann et al 2002) Extensive immunoreactivity for insoluble phosphorylated on serine 129 isoform of alpha-synuclein and ubiquitin, associated with caspase 9 activation in spinal cord of end-stage symptomatic A30P mice. Parkin deficiency mitigated neuritic pathology in end-stage symptomatic A30P mice (Fournier et al 2009) Dopamine transporter knock-out Epidural electrical stimulation of dorsal column in spinal cord restored locomotion (Fuentes et al 2009(Fuentes et al , 2010…”

Section: )mentioning

confidence: 85%

Tracking extranigral degeneration in animal models of Parkinson’s disease: quest for effective therapeutic strategies

Knaryan

Samantaray

Gal

et al. 2011

Journal of Neurochemistry

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Sporadic Parkinson’s disease (PD) is now interpreted as a complex nervous system disorder in which the projection neurons are predominantly damaged. Such an interpretation is based on mapping of Lewy body (LB) and Lewy neurite (LN) pathology. Symptoms of the human disease are much widespread, which span from preclinical nonmotor symptoms and clinical motor symptoms to cognitive discrepancies often seen in advanced stages. Existing symptomatic treatments further complicate with overt drug-irresponsive symptoms. PD is better understood by assimilation of extranigral degenerative pathways with nigrostriatal degenerative mechanisms. The term ‘extranigral’ appeared first in ‘90s’ to more rigorously define the nigral pathology by process of elimination. However, as clinicians progressively identified PD symptoms unresponsive to the gold standard drug L-DOPA, definitions of PD symptoms were redefined. Nonmotor symptoms prodromal to motor symptoms just as preclinical to clinical, and conjointly emerged the concept of nigral versus extranigral degeneration in PD. While nigrostriatal degeneration is responsible for the neurobiological substrates of extrapyramydal motor features, extranigral degeneration corroborates a vast majority of other changes in discrete central, peripheral, and enteric nervous system nuclei which together account for global symptoms of the human disease. As an extranigral site, spinal cord has also been implicated in PD progression. Interconnected to the upper central nervous system structures with descending and ascending pathways, spinal neurons participate in movement and sensory circuits, controlling movement and reflexes. Several clinical and in vivo studies have demonstrated signs of parkinsonism-related degenerative processes in spinal cord, which led to recent consideration of spinal cord as an area of potential therapeutic applications. In nutshell, the review explores how the existing animal models can actually reflect the human disease in order to facilitate PD research. Evolution of extranigral degeneration studies has been succinctly revisited, followed by a survey on animal models in light of recent findings in clinical PD. Together, it may help to develop effective therapeutic strategies.

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Autoradiography of l–Methyl–4–phenyl–l,2,3,6–tetrahydropyridine (MPTP): Uptake in the Monoaminergic Pathways and in Melanin Containing Tissues

Cited by 29 publications

References 19 publications

Pargyline‐Sensitive selective accumulation of a radiolabeled MPTP analog in the primate cerebral cortex and basal ganglia

Pargyline‐Sensitive selective accumulation of a radiolabeled MPTP analog in the primate cerebral cortex and basal ganglia

The function of melanin or six blind people examine an elephant

Tracking extranigral degeneration in animal models of Parkinson’s disease: quest for effective therapeutic strategies

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