Maria J. Guerra

The overall rod performance test in the MPTP-treated-mouse model of Parkinsonism

We investigated the usefulness of the Overall Rotarod Performance (ORP) test for evaluating overall locomotory ability in the 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-injected-mouse model of Parkinsons disease (PD). For this procedure, the mice are pretrained on the rotarod and then tested at a series of increasing speeds, recording the time that the animal remains on the rod at each speed; the overall rod performance (ORP) of each animal is then calculated as the area under the curve in a plot of time-on-the-rod against rotation speed. At 15-day intervals, C57BL/6 mice were injected (or sham-injected) with MPTP, with ORP testing 7-10 days after each injection. After the fourth injection (day 45), mice in the treated group showed clearly lower ORP than mice in the control group (70-90% reduction in ORP), and were thus considered effectively lesioned. Subsequently, we investigated the short-term effects of apomorphine and L-DOPA on ORP in MPTP-treated mice. Apomorphine (at 0.5 or 2.5 mg/kg) had no significant effect, while L-DOPA (at 80 but not at 40 mg/kg) caused almost complete short-term recovery of pretreatment ORP. By about 100 days after the last MPTP injection, MPTP-treated mice showed partial long-term recovery of ORP; at this stage the mice were killed for tyrosine hydroxylase (TH) immunohistochemistry studies. TH immunoreactivity in the striatum showed a strong positive correlation with ORP as tested on day 100. We conclude that the ORP test is useful for evaluating motor deficit in MPTP-treated mice, and the effects of subsequent treatments.

Mechanism of 6-hydroxydopamine neurotoxicity: the role of NADPH oxidase and microglial activation in 6-hydroxydopamine-induced degeneration of dopaminergic neurons

Cell death induced by 6‐hydroxydopamine (6‐OHDA) is thought to be caused by reactive oxygen species (ROS) derived from 6‐OHDA autooxidation and by a possible direct effect of 6‐OHDA on the mitochondrial respiratory chain. However, the process has not been totally clarified. In rat primary mesencephalic cultures, we observed a significant increase in dopaminergic (DA) cell loss 24 h after administration of 6‐OHDA (40 μmol/L) and a significant increase in NADPH subunit expression, microglial activation and superoxide anion/superoxide‐derived ROS in DA cells that were decreased by the NADPH inhibitor apocynin. Low doses of 6‐OHDA (10 μmol/L) did not induce a significant loss of DA cells or a significant increase in NADPH subunit expression, microglial activation or superoxide‐derived ROS. However, treatment with the NADPH complex activator angiotensin II caused a significant increase in all the latter. Forty‐eight hours after intrastriatal 6‐OHDA injection in rats, there was still no loss of DA neurons although there was an increase in NADPH subunit expression and NADPH oxidase activity. The results suggest that in addition to the autooxidation‐derived ROS and the inhibition of the mitochondrial respiratory chain, early microglial activation and NADPH oxidase‐derived ROS act synergistically with 6‐OHDA and constitute a relevant and early component of the 6‐OHDA‐induced cell death.

Brain angiotensin enhances dopaminergic cell death via microglial activation and NADPH-derived ROS

Angiotensin II (AII) plays a major role in the progression of inflammation and NADPH-derived oxidative stress (OS) in several tissues. The brain possesses a local angiotensin system, and OS and inflammation are key factors in the progression of Parkinsons disease. In rat mesencephalic cultures, AII increased 6-OHDA-induced dopaminergic (DA) cell death, generation of superoxide in DA neurons and microglial cells, the expression of NADPH-oxidase mRNA, and the number of reactive microglial cells. These effects were blocked by AII type-1 (AT1) antagonists, NADPH inhibitors, or elimination of glial cells. DA degeneration increased angiotensin converting enzyme activity and AII levels. In rats, 6-OHDA-induced dopaminergic cell loss and microglial activation were reduced by treatment with AT1 antagonists. The present data suggest that AII, via AT1 receptors, increases the dopaminergic degeneration process by amplifying the inflammatory response and intraneuronal levels of OS, and that glial cells play a major role in this process.

The inflammatory response in the MPTP model of Parkinson’s disease is mediated by brain angiotensin: relevance to progression of the disease

The neurotoxin MPTP reproduces most of the biochemical and pathological hallmarks of Parkinson’s disease. In addition to reactive oxygen species (ROS) generated as a consequence of mitochondrial complex I inhibition, microglial NADPH‐derived ROS play major roles in the toxicity of MPTP. However, the exact mechanism regulating this microglial response remains to be clarified. The peptide angiotensin II (AII), via type 1 receptors (AT1), is one of the most important inflammation and oxidative stress inducers, and produces ROS by activation of the NADPH‐oxidase complex. Brain possesses a local angiotensin system, which modulates striatal dopamine (DA) release. However, it is not known if AII plays a major role in microglia‐derived oxidative stress and DA degeneration. The present study indicates that in primary mesencephalic cultures, DA degeneration induced by the neurotoxin MPTP/MPP+ is amplified by AII and inhibited by AT1 receptor antagonists, and that protein kinase C, NADPH‐complex activation and microglial activation are involved in this effect. In mice, AT1 receptor antagonists inhibited both DA degeneration and early microglial and NADPH activation. The brain angiotensin system may play a key role in the self‐propelling mechanism of Parkinson’s disease and constitutes an unexplored target for neuroprotection, as previously reported for vascular diseases.

Sprouting of the serotonergic afferents into striatum after selective lesion of the dopaminergic system by MPTP in adult mice

Neonatal destruction of the nigrostrial dopaminergic (DA) system with 6-hydroxydopamine leads to serotonergic (5-HT) hyperinnervation of the striatum. However, it is not clear whether this occurs in adult animals. We investigated whether serotonergic sprouting occurs in adult mice subjected to bilateral lesion of the DA system by 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). The effects of the lesion were evaluated using a new rotarod test and immunohistochemistry. One hundred days after the last MPTP lesion, there was a clear bilateral serotonergic hyperinnervation throughout the striatum. Additionally, those mice showing the highest reductions in striatal tyrosine hydroxylase (TH) immunoreactivity and in rotarod performance showed the highest density of serotonergic innervation (116% increase). The functional consequences of this process in Parkinsons disease and secondary parkinsonism remain to be clarified.

MECHANISMS OF THE EFFECTS OF EXOGENOUS LEVODOPA ON THE DOPAMINE-DENERVATED STRIATUM

The efficacy of exogenous levodopa (L-DOPA) is attributed to its conversion to dopamine by the enzyme aromatic L-amino-acid decarboxylase in striatal dopaminergic terminals. However, there is controversy about the mechanisms underlying the therapeutic and adverse effects of L-DOPA after almost all striatal dopaminergic afferents have disappeared (i.e. in the later stages of Parkinsons disease). After administration of 30mg/kg or 100mg/kg of L-DOPA, rats subjected to unilateral dopaminergic denervation showed intense contraversive rotation and a high density of Fos-immunoreactive nuclei throughout the denervated striatum, with no significant induction of Fos in the intact striatum. Injection of the central aromatic L-amino-acid decarboxylase inhibitor NSD-1015 30min before and 15min after the injection of L-DOPA suppressed the rotational behavior and the striatal induction of Fos. Comparison of results obtained in rats subjected to unilateral and bilateral dopaminergic denervation indicated that the presence of contralateral dopaminergic innervation does not significantly modulate the effects of L-DOPA on the denervated striatum. Serotonergic denervation led to slight and statistically non-significant decrease in the rotational behavior and Fos expression induced by high doses of L-DOPA (100mg/kg) in the dopamine-denervated striatum, but totally suppressed the rotational behavior and Fos expression induced by low doses of L-DOPA (30mg/kg). The present data indicate that the major effects observed after administration of exogenous L-DOPA are not due to a direct action of L-DOPA on dopamine receptors, or to extrastriatal release of dopamine, but to conversion of L-DOPA to dopamine by serotonergic terminals and probably some intrastriatal cells. Given that serotonergic neurons appear to play an important role in the action of L-DOPA in the later stages of Parkinsons disease, strategies targeting the serotonergic system should be considered for the treatment of Parkinsons disease and for combating undesirable side effects of L-DOPA therapy.

Treadmill running induces striatal Fos expression via NMDA glutamate and dopamine receptors.

Abstract Several non-physiological stimuli (i.e. pharmacological or electrical stimuli) have been shown to induce Fos expression in striatal neurons. In this work, striatal Fos (i.e. Fos-like) expression was studied after physiological stimulation, i.e. motor activity (treadmill running at 36 m/min for 20 min). In rats killed 2 h after the treadmill session, Fos expression was observed in the medial region of the rostral and central striatum, and in the dorsal region of the caudal striatum. Fos expression was prevented by pretreatment with the non-competitive N-methyl-D-aspartate (NMDA) glutamate receptor antagonist MK-801 (0.1 mg/kg) or the D1 dopamine receptor antagonist SCH-23390 (0.1 mg/kg), but not by pretreatment with the D2 receptor antagonist eticlopride (0.5 mg/kg). Thirty-six hours after 6-hydroxydopamine lesion, a considerable reduction in treadmill-induced Fos expression was observed in both sides; however, Fos expression in the lesioned striatum was higher than in the contralateral intact striatum. Several weeks after unilateral 6-hydroxydopamine lesion of the nigrostriatal system, treadmill-induced Fos expression was significantly, but not totally, reduced in the lesioned striatum. Corticostriatal deafferentation also led to considerable reduction in treadmill-induced Fos expression. The present results indicate that exercise induces striatal Fos expression and that, under physiological stimulation, concurrent activation of D1 and NMDA receptors is necessary for such expression to occur. Reduction of Fos expression is practically absolute after acute blockage of these receptors, but not after lesions, possibly due partially to compensatory changes.

Localization and functional significance of striatal neurons immunoreactive to aromatic L-amino acid decarboxylase or tyrosine hydroxylase in rat Parkinsonian models.

Striatal neurons which are immunoreactive (ir) to aromatic L-amino-acid decarboxylase (AADC) or tyrosine hydrodroxylase (TH) may play a role in the decarboxylation of L-DOPA to dopamine (DA) in advanced stages of Parkinsons disease (PD). However, the functional significance of these neurons and the mechanisms responsible for their induction remain to be clarified. In this study, rats were subjected to different types of dopaminergic or serotonergic denervation and L-DOPA injection to study the effects on these neurons. AADC-ir neurons were found in both normal and DA-denervated striata, and no significant differences in their number and distribution were induced following different types of denervation or L-DOPA administration. TH-ir neurons were only found in DA-denervated striata. However, TH-ir neurons did not appear in those areas with maximal DA depletion, but rather were observed near spared or partially lesioned DA terminals. The population of AADC-ir neurons may make a significant contribution to the effects of exogenous L-DOPA in advanced stages of PD. In addition, TH-ir neurons may contribute to these effects, since we have detected AADC-ir in TH-ir neurons using confocal laser scanning microscopy. Finally, neither L-DOPA therapy nor serotonergic denervation induces significant changes in the number or distribution of these neurons.

Involvement of PPAR-γ in the neuroprotective and anti-inflammatory effects of angiotensin type 1 receptor inhibition: effects of the receptor antagonist telmisartan and receptor deletion in a mouse MPTP model of Parkinson's disease

BackgroundSeveral recent studies have shown that angiotensin type 1 receptor (AT1) antagonists such as candesartan inhibit the microglial inflammatory response and dopaminergic cell loss in animal models of Parkinsons disease. However, the mechanisms involved in the neuroprotective and anti-inflammatory effects of AT1 blockers in the brain have not been clarified. A number of studies have reported that AT1 blockers activate peroxisome proliferator-activated receptor gamma (PPAR γ). PPAR-γ activation inhibits inflammation, and may be responsible for neuroprotective effects, independently of AT1 blocking actions.MethodsWe have investigated whether oral treatment with telmisartan (the most potent PPAR-γ activator among AT1 blockers) provides neuroprotection against dopaminergic cell death and neuroinflammation, and the possible role of PPAR-γ activation in any such neuroprotection. We used a mouse model of parkinsonism induced by the dopaminergic neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) and co-administration of the PPAR-γ antagonist GW9662 to study the role of PPAR-γ activation. In addition, we used AT1a-null mice lesioned with MPTP to study whether deletion of AT1 in the absence of any pharmacological effect of AT1 blockers provides neuroprotection, and investigated whether PPAR-γ activation may also be involved in any such effect of AT1 deletion by co-administration of the PPAR-γ antagonist GW9662.ResultsWe observed that telmisartan protects mouse dopaminergic neurons and inhibits the microglial response induced by administration of MPTP. The protective effects of telmisartan on dopaminergic cell death and microglial activation were inhibited by co-administration of GW9662. Dopaminergic cell death and microglial activation were significantly lower in AT1a-null mice treated with MPTP than in mice not subjected to AT1a deletion. Interestingly, the protective effects of AT1 deletion were also inhibited by co-administration of GW9662.ConclusionThe results suggest that telmisartan provides effective neuroprotection against dopaminergic cell death and that the neuroprotective effect is mediated by PPAR-γ activation. However, the results in AT1-deficient mice show that blockage of AT1, unrelated to the pharmacological properties of AT1 blockers, also protects against dopaminergic cell death and neuroinflammation. Furthermore, the results show that PPAR-γ activation is involved in the anti-inflammatory and neuroprotective effects of AT1 deletion.

Reduction of dopaminergic degeneration and oxidative stress by inhibition of angiotensin converting enzyme in a MPTP model of parkinsonism

There is growing evidence indicating that oxidative stress is a key contributor to the pathogenesis and progression of Parkinsons disease. The brain, and particularly the basal ganglia, possesses a local rennin-angiotensin system. Angiotensin activates NAD(P)H-dependent oxidases, which are a major intracellular source of superoxide, and angiotensin converting enzyme inhibitors (ACEIs) have shown antioxidant properties. We treated mice with MPTP and the ACEI captopril to study the possible neuroprotective and antioxidant effects of the latter on the dopaminergic system. Pre-treatment with captopril induced a significant reduction in the MPTP-induced loss of dopaminergic neurons in the substantia nigra and a significant reduction in the loss of dopaminergic terminals in the striatum. Furthermore, captopril reduced the MPTP-induced increase in the levels of major oxidative stress indicators (i.e. lipid peroxidation and protein oxidation) in the ventral midbrain and the striatum. Captopril did not reduce striatal MPP(+) levels, MAO-B activity or dopamine transporter activity, which may reduce MPTP neurotoxicity. Our results suggest that angiotensin-converting enzyme inhibitors may be useful for treatment of Parkinsons disease, and that further investigation should focus on the neuroprotective capacity of these compounds.