Bonifati, V., G. De Michele, et al. (2001). "The parkin gene and
its phenotype. Italian PD Genetics Study Group, French PD Genetics Study Group
and the European Consortium on Genetic Susceptibility in Parkinson's Disease."
Neurol Sci 22(1): 51-2.
Mutations of the parkin gene on chromosome 6 cause autosomal recessive, early
onset parkinsonism. This is the most frequent form of monogenic parkinsonism so
far identified. The associated phenotypical spectrum encompasses early onset,
levodopa-responsive parkinsonism (average onset in the early 30s in Europe), and
it overlaps with dopa-responsive dystonia in cases with the earliest onset, and
with clinically typical Parkinson's disease in cases with later onset. Despite
clinical features, Lewy bodies are not found at autopsy in brains of patients
with parkin mutations. The parkin protein possesses ubiquitin ligase activity,
which is abolished by the pathogenic mutations.
Callizot, N., J. L. Guenet, et al. (2001). "The frissonnant mutant mouse, a
model of dopamino-sensitive, inherited motor syndrome." Neurobiol Dis
8(3): 447-58.
The frissonnant (fri) mutation is an autosomic recessive mutation which
spontaneously appeared in the stock of C3H mice. fri mutant mice have locomotor
instability and rapid tremor. Since tremor ceases when mutant mice have sleep or
are anaesthetized, and because of their obvious stereotyped motor behavior,
these mice could represent an inherited Parkinsonian syndrome. We show here that
the fri/fri mouse fulfills two out of the three criteria required to validate an
experimental model of human disease, that is isomorphism, homology and
predictivity. Indeed, fri/fri mice present an important motor deficit
accompanying visible tremor and stereotypies. They display some memory deficits
as in human Parkinson's desease. l-Dopa and apomorphine (dopaminergic agonists),
ropinirole (selective D2 agonist), and selegiline (an monoamino-oxidase B
[MAO-B] inhibitor) improve their clinical status. However, neither
anatomopathological evidence of nigrostriatal lesion, nor decrease in tyrosine
hydroxylase production could be seen. Copyright 2001 Academic Press.
Hurley, M. J., D. C. Mash, et al. (2001). "Dopamine D(1) receptor expression in
human basal ganglia and changes in Parkinson's disease." Brain Res Mol Brain
Res 87(2): 271-9.
The expression of the human dopamine D(1) receptor was examined by reverse
transcription polymerase chain reaction (RT-PCR) and radioligand binding using
[(3)H]-SCH23390 in post-mortem brain tissue that was obtained from normal
subjects and patients dying with Parkinson's disease who were receiving
treatment with dopaminergic drugs. D(1) receptor mRNA and specific
[(3)H]-SCH23390 binding sites were found in both striatal (nucleus accumbens,
caudate nucleus and putamen) and extrastriatal (globus pallidus and substantia
nigra) brain regions. In parkinsonian brain, D(1) receptor mRNA was increased in
the nucleus accumbens, while a decrease was detected in the substantia nigra
pars compacta. No change in D(1) mRNA levels was found in the other brain areas
examined. An increase in the density of specific [(3)H]-SCH23390 binding sites
was found in the anterior putamen and a decrease in the external segment of the
globus pallidus, no changes were detected elsewhere. This study demonstrates
that regulation of D(1) receptor expression in the brain of patients dying with
Parkinson's disease that were treated with L-DOPA is confined to small
alterations in restricted brain regions.
Iravani, M. M., S. Costa, et al. (2001). "GDNF reverses priming for dyskinesia
in MPTP-treated, L-DOPA-primed common marmosets." Eur J Neurosci 13(3):
597-608.
Parkinson's disease (PD) is associated with a progressive loss of dopamine
neurons in the substantia nigra and degeneration of dopaminergic terminals in
the striatum. Although L-DOPA treatment provides the most effective symptomatic
relief for PD it does not prevent the progression of the disease, and its
long-term use is associated with the onset of dyskinesia. In rodent and primate
studies, glial cell line-derived neurotrophic factor (GDNF) may prevent 6-OHDA-
or MPTP-induced nigral degeneration and so may be beneficial in the treatment of
PD. In this study, we investigate the effects of GDNF on the expression of
dyskinesia in L-DOPA-primed MPTP-treated common marmosets, exhibiting dyskinesia.
GDNF or saline was administered by two intraventricular injections, 4 weeks
apart, to MPTP-treated, L-DOPA-treated common marmosets primed to exhibit
dyskinesia. Prior to GDNF or saline administration, all animals displayed marked
dyskinesia when treated with L-DOPA. GDNF administration produced a significant
improvement in motor disability and, following the second injection of GDNF, a
significant improvement in the locomotor activity was observed. Following the
administration of L-DOPA there was a greater reversal of disability and a
reduction in the intensity of L-DOPA-induced dyskinesia in GDNF-treated animals
compared to saline-treated controls. However, there was no significant
difference in L-DOPA's ability to increase locomotor activity between GDNF-treated
and saline-treated animals. GDNF treatment caused a significant increase in the
number of tyrosine hydroxylase-positive neurons in the substantia nigra, but no
change in [(3)H]mazindol binding to dopamine terminals was found in the striatum
of GDNF-treated animals compared to saline-treated controls. In GDNF-treated
animals a small but significant reduction in enkephalin mRNA was observed in the
caudate nucleus but not in the putamen or the nucleus accumbens. Substance P
mRNA expression was equally reduced in the caudate nucleus and the putamen of
the GDNF-treated animals but not in the nucleus accumbens. Intraventricular
administration of GDNF improved MPTP-induced disability and reversed dopamine
cell loss in the substantia nigra. GDNF also diminished L-DOPA-induced
dyskinesia, which may relate to its ability to partly restore nigral
dopaminergic transmission or to modify the activity of striatal output pathways.
Kang, U. J., W. Y. Lee, et al. (2001). "Gene therapy for Parkinson's disease:
determining the genes necessary for optimal dopamine replacement in rat models."
Hum Cell 14(1): 39-48.
This article reviews the mechanism of dopamine delivery in the CNS in order to
determine the optimal set of genes for effective gene therapy in Parkinson's
disease (PD). Systematic neurobiological investigation of the biochemical steps
has revealed that tyrosine hydroxylase (TH), which has been used in earlier
studies, functions only when the essential cofactor, tetrahydrobiopterin (BH1)
is present. Transduction of the gene for GTP cyclohydrolase I, the first and
rate-limiting step in BH1 synthesis, along with the TH gene, generated cells
that are capable of producing L-DOPA spontaneously both in vitro and in vivo.
When the aromatic L-amino acid decarboxylase (AADC) gene was added as a third
gene, in an attempt to increase the conversion of L-DOPA to dopamine, feedback
inhibition by the end product, dopamine, on TH activity resulted. To circumvent
this problem, we employed a complementary strategy. Gene transfer of the
vesicular monoamine transporter was combined with AADC and produced genetically
modified cells that can convert L-DOPA to dopamine and store it for gradual
release. This approach provided a means to regulate final dopamine delivery by
controlling precursor doses and to achieve more sustained delivery of dopamine.
Our investigation into determining the genes necessary for optimal dopamine
delivery has been facilitated by in vivo biochemical assays using microdialysis.
This technique has provided us with a clear and quantitative tool to compare the
effects of various genes involved in dopamine synthesis and processing.
Lindvall, O. and P. Hagell (2001). "Cell therapy and transplantation in
Parkinson's disease." Clin Chem Lab Med 39(4): 356-61.
Transplanted human fetal dopamine neurons can reinnervate the striatum in
patients with Parkinson's disease (PD). Recent findings using positron emission
tomography indicate that the grafts are functionally integrated and restore
dopamine release in the patient's striatum. The grafts can exhibit long-term
survival without immunological rejection and despite an ongoing disease process
and continuous antiparkinsonian drug treatment. In the most successful cases,
patients have been able to withdraw L-dopa treatment after transplantation and
resume an independent life. About two-thirds of grafted patients have shown
clinically useful, partial recovery of motor function. The major obstacle for
the further development of this cell replacement strategy is that large amounts
of human fetal mesencephalic tissue are needed for therapeutic effects. Stem
cells hold promise as a virtually unlimited source of self-renewing progenitors
for transplantation. The possibility to generate dopamine neurons from such
cells is now being explored using different approaches. However, so far the
generated neurons have survived poorly after transplantation in animals.
Martinez, A., P. M. Knappskog, et al. (2001). "A structural approach into human
tryptophan hydroxylase and its implications for the regulation of serotonin
biosynthesis." Curr Med Chem 8(9): 1077-91.
Tryptophan hydroxylase (TPH) catalyzes the 5-hydroxylation of tryptophan, which
is the first step in the biosynthesis of indoleamines (serotonin and melatonin).
Serotonin functions mainly as a neurotransmitter, whereas melatonin is the
principal hormone secreted by the pineal gland. TPH belongs to the family of the
aromatic amino acid hydroxylases, including phenylalanine hydroxylase (PAH) and
tyrosine hydroxylase (TH), which all have a strict requirement for dioxygen,
non-heme iron (II) and tetrahydrobiopterin (BH4). During the last three years
there has been a formidable increase in the amount of structural information
about PAH and TH, which has provided new insights into the active site
structure, the binding of substrates, inhibitors and pterins, as well as on the
effect of disease-causing mutations in these hydroxylases. Although structural
information about TPH is not yet available, the high sequence homology between
the three mammalian hydroxylases, notably at the catalytic domains, and the
similarity of the reactions that they catalyze, indicate that they share a
similar 3D-structure and a common catalytic mechanism. Thus, we have prepared a
model of the structure of TPH based on the crystal structures of TH and PAH.
This structural model provides a frame for understanding the specific
interactions of TPH with L-tryptophan and substrate analogues, BH4 and cofactor
analogues, L-DOPA and catecholamines. The interactions of these ligands with the
enzyme are discussed focusing on the physiological and pharmacological
regulation of serotonin biosynthesis, notably by tryptophan supplementation
therapy and substitution therapy with tetrahydrobiopterin analogues (positive
effects), as well as the effect of catecholamines on TPH activity in L-DOPA
treated Parkinson's disease patients (enzyme inhibition).
McNaught, K. S. and P. Jenner (2001). "Proteasomal function is impaired in
substantia nigra in Parkinson's disease." Neurosci Lett 297(3):
191-4.
The accumulation of alpha-synuclein, ubiquitin and other proteins in Lewy bodies
in degenerating dopaminergic neurones in substantia nigra in idiopathic
Parkinson's disease (PD) suggest that inhibition of normal/abnormal protein
degradation may contribute to neuronal death. We now show for the first time
that the chymotrypsin- (39%), trypsin- (42%) and postacidic-like (33%)
hydrolysing activities of 20/26S proteasome are impaired in substantia nigra in
PD. Proteasome inhibition does not appear to result from drug treatment since
high concentrations of L-3,4-dihydroxyphenylalanine had no effect on enzymatic
activity in vitro. These observations provide the first direct evidence that
inhibition of the ubiquitin-proteasome pathway leading to altered protein
handling and Lewy body formation may be responsible for degeneration of the
nigrostriatal pathway in idiopathic PD.
Muller, T., D. Woitalla, et al. (2001). "Decrease of methionine and S-adenosylmethionine
and increase of homocysteine in treated patients with Parkinson's disease."
Neurosci Lett 308(1): 54-6.
Levodopa is administered with dopa decarboxylase inhibitors (DDI) to prevent its
peripheral degradation. This increases conversion of levodopa to 3-O-methyldopa
(3-OMD) by catechol-O-methyltransferase (COMT). S-adenosylmethionine (SAM),
which is synthesized from adenosine triphosphate and methionine (MET), serves as
methyl donor for this O-metabolisation of levodopa with resulting conversion of
SAM to total homocysteine (tHcy) via S-adenosylhomocysteine (SAH). Previous
studies showed augmented plasma levels of tHcy in long-term levodopa/DDI-treated
patients with Parkinson's disease (PP). Objective of this study was to compare
MET, SAM, levodopa, 3-OMD, tHcy and SAH in plasma of 20 levodopa/DDI treated PP
and corresponding controls. A significant decrease of MET respectively SAM and
an increase of tHcy appeared in PP. SAH with its short half-life did not differ.
Levodopa/DDI long-term treatment contributes to altered levels of substrates of
the O-methylation cycle in PP.
Pirker, W., J. Tedroff, et al. (2001). "Coadministration of (-)-OSU6162 with l-DOPA
normalizes preproenkephalin mRNA expression in the sensorimotor striatum of
primates with unilateral 6-OHDA lesions." Exp Neurol 169(1):
122-34.
The substituted phenylpiperidine (-)-OSU6162 is a novel modulator of the
dopaminergic systems with low affinity for dopamine D(2) receptors and potent
normalizing effects on l-DOPA-induced dyskinesias. We studied the effects of
coadministration of (-)-OSU6162 with l-DOPA on the regulation of striatal
preproenkephalin (PPE) and prodynorphin (PDyn) mRNA expression in the primate
brain by in situ hybridization histochemistry. Common marmoset monkeys
sustaining unilateral 6-hydroxydopamine lesions of the nigrostriatal pathway
received l-DOPA/carbidopa, l-DOPA/carbidopa plus (-)-OSU6162, or vehicle over 14
days. In vehicle-treated animals, PPE mRNA levels were markedly increased in the
sensorimotor territory of the lesioned striatum. By contrast, a rather uniform
lesion-induced reduction of PDyn mRNA levels was found in the vehicle group.
Subchronic l-DOPA treatment induced a further increase in PPE mRNA expression in
a number of sensorimotor and associative subregions of the denervated striatum.
Coadministration of (-)-OSU6162 with l-DOPA partially reversed the lesion- and
l-DOPA-induced elevation of PPE expression and, by affecting PPE mRNA expression
differentially on the intact and lesioned striatum, markedly reduced the
side-to-side difference in PPE mRNA expression. The effects on PPE mRNA
expression were apparent throughout the rostrocaudal extent of the putamen and
the dorsal portions of the caudate nucleus. l-DOPA treatment resulted in an
enhancement in PDyn mRNA expression in all functional compartments of the
striatum. Coadministration of (-)-OSU6162 had no apparent influence on these l-DOPA-induced
changes in PDyn mRNA expression. The present results suggest that (-)-OSU6162
acts primarily by modifying striatal output via the indirect pathway. Copyright
2001 Academic Press.
Racette, B. A., L. McGee-Minnich, et al. (2001). "Welding-related parkinsonism:
clinical features, treatment, and pathophysiology." Neurology 56(1):
8-13.
OBJECTIVE: To determine whether welding-related parkinsonism differs from
idiopathic PD. BACKGROUND: Welding is considered a cause of parkinsonism, but
little information is available about the clinical features exhibited by
patients or whether this is a distinct disorder. METHODS: The authors performed
a case-control study that compared the clinical features of 15 career welders,
who were ascertained through an academic movement disorders center and compared
to two control groups with idiopathic PD. One control group was ascertained
sequentially to compare the frequency of clinical features, and the second
control group was sex- and age-matched to compare the frequency of motor
fluctuations. RESULTS: Welders were exposed to a mean of 47,144 welding hours.
Welders had a younger age at onset (46 years) of PD compared with sequentially
ascertained controls (63 years; p < 0.0001). There was no difference in
frequency of tremor, bradykinesia, rigidity, asymmetric onset, postural
instability, family history, clinical depression, dementia, or drug-induced
psychosis between the welders and the two control groups. All treated welders
responded to levodopa. Motor fluctuations and dyskinesias occurred at a similar
frequency in welders and the two control groups. PET with 6-[18F]fluorodopa
obtained in two of the welders showed findings typical of idiopathic PD, with
greatest loss in posterior putamen. CONCLUSIONS: Parkinsonism in welders is
distinguished clinically only by age at onset, suggesting welding may be a risk
factor for PD. These preliminary data cannot exclude a genetic contribution to
susceptibility in these exposed individuals.
Schwarz, E. J., R. L. Reger, et al. (2001). "Rat marrow stromal cells rapidly
transduced with a self-inactivating retrovirus synthesize L-DOPA in vitro."
Gene Ther 8(16): 1214-23.
Autologous bone marrow stromal cells engineered to produce
3,4,-dihydroxyphenylalanine (L-DOPA) can potentially be used as donor cells for
neural transplantation in Parkinson's disease. Here, we examined the possibility
of using several different promoters and either a self-inactivating retrovirus (pSIR)
or standard retroviruses to introduce into marrow stromal cells (MSCs), the two
genes necessary for the cells to synthesize L-DOPA. pSIR vectors were
constructed using the mouse phosphoglycerate kinase-1 (PGK) promoter or the
cytomegalovirus (CMV) promoter to drive expression of either a GFP reporter gene
or a bicistronic sequence containing the genes for human tyrosine hydroxylase
type I (TH) and rat GTP cyclohydrolase I (GC) separated by an internal ribosome
entry site (IRES). rMSCs were successfully transduced with both standard
retroviral vectors and pSIR containing the PGK promoter. Transduced rMSCs
expressed GFP (90.4--94.4% of cells) or were able to synthesize and secrete
L-DOPA (89.0--283 pmols/10(6) cells/h). After transduced rMSCs were plated at
low density (3--6 cells/cm(2)), the cells expanded over 1000-fold in 3--4 weeks,
and the rMSCs continued to either express GFP or produce L-DOPA. Furthermore,
two high-expressing clones were isolated and expanded at low-density from rMSCs
transduced with pSIR driven by the PGK promoter (97.0% GFP+ or 1096.0 pmols
L-DOPA/10(6) cells/h).
Weingarten, P. and Q. Y. Zhou (2001). "Protection of intracellular dopamine
cytotoxicity by dopamine disposition and metabolism factors." J Neurochem
77(3): 776-85.
Dopamine has been hypothesized as a contributing factor for the selective
degeneration of dopaminergic neurons in Parkinson's disease. However, the
cytotoxic mechanisms of dopamine and its metabolites remain poorly understood.
Using a stable aromatic amino acid decarboxylase (AADC) expressing a fibroblast
cell line, we previously demonstrated a novel, non-oxidative cytotoxicity of
intracellular dopamine. In this study, we further investigate the roles of
dopamine metabolism and disposition proteins against intracellular dopamine
cytotoxicity by co-expressing these factors in AADC-expressing cells. Our
results indicate that overexpression of the vesicular monoamine transporter and
monoamine oxidase A-induced protection against intracellular dopamine toxicity,
and conversely that pharmacological inhibition of these pathways potentiated
L-DOPA toxicity in catecholaminergic PC12 cells. Macrophage migration inhibitory
factor and glutathione S-transferase (GST), factors that have recently been
shown to be involved in dopamine metabolism, also exhibited a strong protective
role against intracellular dopamine cytotoxicity. Our results support a
potential role for non-oxidative cytoplasmic dopamine toxicity, and imply that
disruption in dopamine disposition and/or metabolism could underlie the
progressive degeneration of dopaminergic neurons in Parkinson's disease.
Zhao, W. Q., L. Latinwo, et al. (2001). "L-dopa upregulates the expression and
activities of methionine adenosyl transferase and catechol-O-methyltransferase."
Exp Neurol 171(1): 127-38.
High nonphysiological doses of l-dopa are administered to Parkinson's disease
(PD) patients, to replenish the depleted dopamine (DA). A large portion of the
administered L-dopa and the newly formed DA undergoes methylation by reacting
with S-adenosyl-L-methionine (SAM). In the process SAM, as well as L-dopa and
DA, is utilized and great demands are placed on the transmethylation system. In
this study we investigated whether L-dopa increases the transmethylation process
by inducing methionine adenosyl transferase (MAT), the enzyme that produces SAM,
and catechol-O-methyl transferase (COMT), the enzyme that transfers the methyl
group from SAM to L-dopa and DA. Swiss Webster mice were injected with L-dopa,
four times/day, for 1 to 16 days. Brain DA, 3-O-methyldopa (3-OMD), SAM, S-adenosylhomocysteine
(SAH), MAT, and COMT were measured following a 24-h withdrawal period. An
increase of 264% of brain DA occurred at days 2 and 3 after which it tapered to
about 164% of control. The brain level of 3-OMD increased to 870% of the
control. SAM was increased by 44% after the sixth day and SAH level was about
double after the second day. After day 3, MAT activity was increased by about
35%. Western blot analysis showed that MAT is more clearly characterized in 10%
mercaptoethanol reducing buffer in which 31.5-, 38- (beta), and 48-kDa
(alpha1/alpha2) subunits were distinctly revealed. The induction of the 38-kDa
and, more prominently, the 48-kDa subunits of MAT and the potential
transactivator proteins of MAT, c-Jun/AP-1, was evident by day 6. The 31.5-kDa
subunit was downregulated. COMT was detected as 24.7-, 30-, and 47.5-kDa bands
in the brain, consistent with the membrane-bound COMT I (MB-COMT) and the
dimeric COMT II. The 24.7- and the 30-kDa MB-COMT bands were induced in the
brain by day 6 and peaked on day 9. The highlight of the study is the fact that
L-dopa induces the enzymes MAT and COMT. In addition, the downturn in brain DA
after the sixth day coincides with the increase in SAM and the 48-kDa MAT
protein. Thus, during PD treatment with L-dopa the induction of MAT and COMT is
likely to occur and in turn increase the methylation and reduction of L-dopa and
DA that may help cause the tolerance or the wearing-off effect developed to
L-dopa.
