Evaluation of exercise-induced modulation of glial activation and dopaminergic damage in a rat model of Parkinson’s disease using [ 11 C]PBR28 and [ 18 F]FDOPA PET

Introduction

Parkinson’s disease (PD) is the second most common neurodegenerative disease among elderly and affects approximately 30 million people worldwide. ¹ PD patients account for a large portion of healthcare expenditures and represents a huge social and economic burden.^2,3 Thus, adequate prevention and treatment strategies for PD are required.

One possible strategy to delay the onset and progression of PD is regular exercise since exercise was found to be inversely related to the incidence of neurodegenerative diseases.^4,5 Exercise is a cheap and widely practiced activity that stimulates the molecular and cellular cascades that support and maintain brain plasticity.^6,7 Intermittent exercise can lead to improvement of the dopaminergic system and recovery of motor behavior in an animal model of PD. ⁸ Exercise induces an increase in the neurotrophic factors, that play an important role in central nervous system protection and recovery.^5,9,10 An increase in neurotrophic factors in the nigrostriatal system can improve mitochondrial function and protect neurons from the detrimental effects of a neurotoxin. ¹¹ Besides neurotrophic factors, vascular endothelial growth factor and insulin growth factor 1 can reduce the levels of pro-apoptotic proteins and thus seem to indirectly participate in neuroprotection.^5,7 This suggests that exercise may reduce the risk of developing neurodegenerative disorders and delay disease progression. ⁵ To enable monitoring of the protective effects of exercise on brain functions in longitudinal study designs and to facilitate the translation of preclinical results to humans, noninvasive functional imaging tools would be desirable.

Positron emission tomography (PET) is an attractive tool for acquiring functional information on pathological processes in the brain. 6-[¹⁸F]Fluoro-L-3,4-dihydroxyphenylalanine ([¹⁸F]FDOPA) has been used as a PET tracer to monitor aromatic L-amino acid decarboxylase (AADC) activity in dopaminergic neurons. Since AADC is responsible for the conversion of DOPA into dopamine, [¹⁸F]FDOPA PET has been used as surrogate marker for the dopamine synthesis rate and presynaptic dopaminergic neuronal integrity. A decline in tracer uptake in striatum correlates with the severity of dopaminergic dysfunction. ¹² [¹⁸F]FDOPA PET enables the detection of presynaptic dopaminergic deficits in PD patients with excellent sensitivity and specificity, even in the early phases of the disease. ¹³ Thus, [¹⁸F]FDOPA PET could be a useful tool to evaluate the efficacy of novel treatment strategies for PD, like exercise.^14,15

Neuroinflammation can be detected in PD patients before a decrease in dopaminergic function can be observed with [¹⁸F]FDOPA PET. ¹⁶ Glial activation is an important hallmark of neuroinflammation. Upon activation, microglia and astrocytes increase the expression of the 18kD-translocator protein (TSPO) in the outer mitochondrial membrane.^17–20 Overexpression of TSPO can be detected by PET with a suitable tracer. The TSPO ligand [¹¹C]-(R)-PK11195 has been most frequently used to evaluate glial activation. However, this PET tracer has some limitations^21,22 and therefore second generation of TSPO PET tracers has been developed. [¹¹C]PBR28 is a second generation TSPO tracer that has been applied successfully in both preclinical and clinical studies.^17,21–23

In the present study, we aimed to investigate the beneficial effects of exercise on glial activation and dopaminergic system degeneration in a PD model, using [¹¹C]PBR28 and [¹⁸F]FDOPA PET, respectively. Postmortem immunohistochemical analysis was performed to confirm PET imaging results. As an animal model for PD, rats were treated by unilateral striatal injection of 6-hydroxydopamine (6-OHDA). Motor and cognitive functions were assessed in behavioral tests and correlated to imaging data.

Material and methods

Results

[¹¹C]PBR28 PET

[¹¹C]PBR28 uptake was analyzed for total midbrain, since the SNc could not be reliably delineated in the PET images due to the limited spatial resolution of the PET camera (1.4 mm). Tracer uptake in the affected midbrain did not significantly differ between groups at any time point (baseline [F(3,52) = 0.42; p = 0.74]; day 10 [F(3,48) = 0.499, p = 0.068]; day 30 [F(3,50) = 0.75, p = 0.52]) and neither did the ratio between the affected and control midbrain (baseline [F(3,26) = 0.88; p = 0.47]; day 10 [F(1,24) = 1.44, p = 0.24]; day 30 [F(1,25) = 0.11, p = 0.74]) (Supplementary data – Table 5). [¹¹C]PBR28 uptake in the affected striatum of the SED + PD group was significantly increased at day 10 (F(3,48) = 4.68, p = 0.006), but not at baseline (F(3,52) = 2.049; p = 0.12) or day 30 (F(3,50) = 0.55, p = 0.65). Consequently, the uptake ratio between hemispheres in the SED + PD group at day 10 was significantly higher when compared to baseline (60%, p < 0.0001) and to the striatal uptake ratio in other groups at day 10 (ca. 49%, p < 0.01F(1,24) = 7.55, p = 0.01). At day 30, no significant differences in striatal uptake between hemispheres or between groups were observed anymore [F(1,25) = 2.46; p = 0.13] (Figure 3). In hippocampus, there was no significant difference in tracer uptake between hemispheres or between groups at baseline [F(3,26) = 0.62; p = 0.61]. At day 10, SED + PD animals showed significant effects for 6-OHDA injection [F(1,26) = 5.50; p = 0.03] and for exercise [F(1,26) = 5.74; p = 0.03]. In particular, [¹¹C]PBR28 uptake in the affected hippocampus of SED + PD rats was significantly increased when compared to baseline and to other groups at day 10 (ca. 30%, p < 0.001) [F(1,26) = 7.55, p = 0.01]. No significant differences in hippocampal [¹¹C]PBR28 uptake were observed anymore at day 30 [F(1,25) = 2.16; p = 0.15] (Figure 4) (Supplementary data – Table 5). OPEN IN VIEWER

Figure 3.

Results of [¹¹C]PBR28 PET at baseline, 10 days and 30 days after surgery. (a) Tracer uptake in the experimental (right) and control (left) striatum, expressed as Standard Uptake Value (SUV). (b) Tracer uptake ratio between experimental and control striatum. (c) Examples of transaxial [¹¹C]PBR28 PET images of the striatal region acquired at day 10 after surgery. The hemisphere of sedentary animals in which 6-OHDA was injected shows increased [¹¹C]PBR28 uptake (red arrow). Note that exercise reversed this effect, resulting in a normalization of [¹¹C]PBR28 uptake in the EX + PD group (green arrow). Sedentary controls (SED); Exercised controls (EX); Sedentary PD rats (SED + PD); and exercised PD rats (EX + PD). Standard uptake value (SUV). Statistical differences between groups for the same brain hemisphere and between hemispheres for same group are presented as *p < 0.05; **p < 0.01; ***p < 0.001; statistical differences between baseline and day 10 and 30 are indicated by ^# p < 0.05; ^## p < 0.01; ^#### p < 0.0001.

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Figure 4.

Results of [¹¹C]PBR28 PET at baseline, 10 days and 30 days after surgery. (a) Tracer uptake in the experimental (right) and control (left) hippocampus, expressed as Standard Uptake Value (SUV). (b) Tracer uptake ratio between experimental and control hippocampus. (c) Examples of transaxial [¹¹C]PBR28 PET images of the hippocampus region acquired at day 10 after surgery. The hemisphere of sedentary animals in which 6-OHDA was injected shows increased [¹¹C]PBR28 uptake (red arrow). Note that exercise reversed this effect, resulting in a normalization of [¹¹C]PBR28 uptake in the EX + PD group (green arrow). Sedentary controls (SED); Exercised controls (EX); Sedentary PD rats (SED + PD); and exercised PD rats (EX + PD). Standard Uptake Value (SUV). Statistical differences between groups for the same brain hemisphere and between hemispheres for same group are presented as *p < 0.05; **p < 0.01; ***p < 0.001; ***p < 0.0001. Statistical differences between baseline and day 10 and 30 are indicated by ^### p < 0.001.

Discussion

The present study showed that exercise is able to suppress neurotoxin-induced glial activation, reduce degeneration of the dopaminergic system and normalize memory and motor deficits in a rat model of PD. Exercise has been suggested as a potential intervention in neurodegenerative diseases. However, its beneficial effects were only determined indirectly by assessment of clinical symptoms or postmortem tissue analysis. In this study, we directly demonstrated the effects of exercise on glial activation and the dopaminergic system in a noninvasive manner using PET. Imaging results were confirmed by postmortem immunohistochemical analysis.

Previous studies demonstrated that injection of 6-OHDA in striatum increases the expression of microglial markers and decreases TH expression. ⁴² Despite the small sample size for immunohistochemistry on day 10, Iba-1 staining in this study confirmed that unilateral 6-OHDA injection in striatum causes robust microglial activation, not only in striatum, but also in SNc and hippocampus of sedentary PD rats. At day 30, activated microglia were still present in SNc, but not in striatum and hippocampus. [¹¹C]PBR28 PET provided similar results as Iba-1 staining for striatum and hippocampus, but could not detect glial activation in SNc. This can be explained by the limited spatial resolution of the PET camera, which precluded analysis of small brain structures, like SNc, in rats. When the whole midbrain was analyzed instead, glial activation could not be detected since the specific signal derived from SNc was averaged out over a large volume (partial volume effect). 6-OHDA injection not only caused microglia activation, but also increased astrocyte density in the striatum of sedentary rats, but not in SNc or hippocampus. Sustained exercise was hypothesized to have anti-inflammatory properties that can counteract the effect of 6-OHDA. In this study, both Iba-1 staining and PET imaging showed that intermittently forced exercise could indeed suppress the activation of microglia in striatum, SNc and hippocampus. In line with our observation, previous studies described that exercise reduces the number of circulating pro-inflammatory monocytes and increases the number of regulatory T cells. In addition, levels of anti-inflammatory and neuroprotective molecules are enhanced in peripheral blood after physical activity. ⁷ However, the mechanism through which exercise affects the immune system is not fully understood yet.

At day 30, microglia activation had spontaneously resolved in striatum and hippocampus, but not in SNc. Microglia activation in SNc seems to be associated with persistent dopaminergic injury. This observation is in line with other studies in animals and postmortem studies on brain tissue of PD patients. ⁴³ Attempts to elucidate how activated microglia contribute to neuronal loss in the SNc have generated conflicting results. ⁴³ In EX + PD animals, this persisting microglia activation appeared to have caused somewhat less degeneration of the dopaminergic system in SNc. Exercise may have changed the phenotype of microglia in SNc from the pro-inflammatory M1 to the anti-inflammatory M2-phenotype before resolving to the resting state. ⁷ A shortcoming of our study is that neither PET imaging nor Iba-1 staining provided information about the phenotype of the activated microglia.

In contrast to its modulatory effect on microglia activation, exercise was not able to suppress the activation of astrocytes in the striatum 10 days after surgery in our study. Others, however, did observe a modulatory effect of exercise on 6-OHDA-induced astrocyte activation, which seemed to be associated with improved motor function. ⁴⁴ In that study, a higher dose of 6-OHDA (10 vs. 3 µg) was injected into the medial forebrain bundle, resulting in persistent astrocyte activation in sedentary animals up to day 32. Moreover, a more intense running protocol was used, which may have caused a greater effect on astrocytes. Despite contradictory evidence in the literature, our data suggest that exercise mainly has a modulatory effect on microglia rather than on astrocytes. In our study, astrocyte activation was only observed in dorsolateral striatum close to the injection site, both in control and PD animals. These data corroborate a previous study that observed an astrocyte reaction close to the needle track in rats injected with vehicle solution. ⁴⁵ These activated astrocytes might be mainly involved in restoration of damage to affected tissue by inducing glial scar formation. ⁴⁶

Our data showed that unilateral 6-OHDA injection had a detrimental effect on the dopaminergic system in sedentary animals, as demonstrated by both [¹⁸F]FDOPA PET and TH staining. However, dopaminergic damage in striatum appears to induce a compensatory response, since the reduction in TH staining was larger at day 10 after 6-OHDA injection than at day 30. In SNc, such a spontaneous recovery was not observed. This is in line with studies that revealed that surviving dopaminergic neurons increase the dopamine production, trying to compensate neuronal loss. Exercise can intensify this compensatory mechanisms. ¹⁰

Exercise resulted in a partial reduction of dopaminergic damage in the striatum at day 10 and complete recovery at day 30. Exercise has been linked to protection of the dopaminergic system by increasing the release of neurotrophic factors that can have anti-inflammatory properties.^5,7,8,10 The exercise-induced reduction in dopaminergic damage observed in our study seems, therefore, to be connected to the modulatory effect of exercise on glial activation in striatum, which could in turn have resulted in prevention of inflammation-induced neuronal damage. In SNc, however, exercise did not have any effect on TH staining at day 10 at all, but resulted in partial recovery of the dopaminergic damage at day 30. This indicates that there was a decrease in the TH expression at day 10, but neurons were not dead yet.

[¹⁸F]FDOPA PET results were highly correlated with postmortem TH staining and reduced striatal tracer uptake was associated with motor symptoms. Kyono et al. ¹² showed that tracer uptake correlated negatively with the severity of dopaminergic dysfunction. In another study, poor motor performance was directly linked to a decline in striatal [¹⁸F]FDOPA uptake. ⁴⁷ Prolonged reaction and movement time were related to lower [¹⁸F]FDOPA uptake in the caudate nucleus, and abnormalities in hand fine force control were related to striatal [¹⁸F]FDOPA uptake. These findings provide evidence that regional loss of nigrostriatal inputs to frontostriatal networks affects specific aspects of motor function.

A relatively mild model of PD was used in our study to enable detection of the beneficial effects of exercise. The mild severity of the model was confirmed by the observation that intra-striatal injection of the neurotoxin 6-OHDA only had an effect on body weight in the first week after surgery, but did not cause any impairment of motor activity in the open field test or cylinder test at day 28/29. Previous studies showed deficits in motor activity when 80% of the dopaminergic cells had been killed, while 55% of neuronal death did not change locomotion.^48,49 Apparently, in our study, dopaminergic loss at day 28/29 was insufficient to evoke an effect on motor activity. On the other hand, at day 9 after 6-OHDA injection, the cylinder test detected significant asymmetry in forelimb use in sedentary rats. This apparent discrepancy could be ascribed to more severe loss of dopamine synthesis at this time point, as TH staining in striatum was reduced by approximately 50% at day 10, whereas only a 20% reduction was found at day 30. Another possible explanation for improved asymmetry forelimb use for SED + PD animals at day 29 may be a compensatory mechanism of the contralateral hemisphere, since the lesion of our model is unilateral. ⁵⁰ If a compensatory mechanism was present, however, it did not result in increased [¹⁸F]FDOPA uptake in the control hemisphere. In contrast, previous studies did reveal compensatory changes in the control hemisphere. This apparent discrepancy can be explained by the mild PD model used in our study, with dopaminergic loss being only 30–50%. Compensatory mechanisms in the contralateral hemisphere were described in unilateral PD models with dopaminergic loss of more than 60%.^51–55

Interestingly, intermittently forced exercise reduced the degree of dopaminergic loss (−30%) at day 9 after 6-OHDA injection, resulting in normalization of forelimb use in the cylinder test. Apparently, there is a threshold for the amount of dopaminergic damage that is required to induce motor symptoms. Improvement in motor function as a result of exercise has been associated with increased plasticity and dendritic spines, ⁵⁶ which could have been induced by the release of neurotrophic factors.^5,7,8,10

Non-motor symptoms, including memory impairment, usually already appear in early stages of PD and are increasingly recognized as a major challenge in the treatment. Our study showed that injection of 6-OHDA affects both short-term and long-term memory in sedentary animals. The role of the dopaminergic system in the NOR test has been demonstrated in pharmacological studies, in which D1 and D2/D3 antagonists were applied. ⁵⁷ 6-OHDA-induced dopaminergic loss in caudate and substantia nigra leads to dysfunction of the prefrontal cortex, an area involved short-term memory. ⁵⁸ Previous studies have also linked microglia activation to non-motor symptoms in neurodegenerative diseases. ⁵⁹ We observed activation of microglia, not only in the dopaminergic system but also in the hippocampus, a brain region associated with memory function. Memory deficits observed in our study may therefore also be related to activation of microglia in hippocampus at day 10. Exercise was able to suppress microglia activation in hippocampus, which could also have been responsible for the prevention of the deleterious effects of 6-OHDA on memory. Moreover, exercise may have increased neuroplasticity of corticostriatal circuits, resulting in modulation of dopamine and glutamate neurotransmission, synaptogenesis, and cerebral blood flow. ⁶⁰ Thus, exercise may be able to improve cognitive function in PD by either preventing dopaminergic loss or suppressing glial activation.

Conclusions

The present study corroborates previous findings suggesting intermittent exercise could have the potential to become an (add-on) non-pharmacological intervention for PD. Exercise has a modulating effect on activation of microglia after exposure to 6-hydroxydopamine. Exercise-induced attenuation of microglia seems to have a beneficial effect on preservation and/or recovery of the dopaminergic system, cognition and motor function. The present study also demonstrated that PET enables noninvasive, longitudinal monitoring of the modulating effects of exercise on glial activation and degeneration of presynaptic dopaminergic neurons. The modulating effect of exercise, the 6-OHDA-induced glial activation measured by [¹¹C]PBR28 PET was confirmed by Iba-1 staining, whereas [¹⁸F]FDOPA PET correlated well with TH staining and behavioral symptoms. These results warrant elaborate longitudinal studies assessing the beneficial effects of exercise on PD progression using PET.