Glial cell response: A pathogenic factor in Parkinson's disease

Parkinson's disease (PD) is a common neurodegenerative disorder characterized by the progressive loss of dopaminergic neurons in the substantia nigra pars compacta (SNpc). The loss of these neurons is associated with a glial response composed mainly of activated microglial cells and, to a lesser extent, of reactive astrocytes. This glial response may be the source of trophic factors and can protect against reactive oxygen species and glutamate. Alternatively, this glial response can also mediate a variety of deleterious events related to the production of pro-oxidant reactive species, proinflammatory prostaglandin, and cytokines. In this review, the authors discuss the potential protective and deleterious effects of glial cells in the SNpc of PD and examine how these factors may contribute to the pathogenesis of this disease.     

Motor response to repeated dopaminergic stimulation in Parkinson's disease.

Recent studies giving subcutaneous apomorphine or intravenous levodopa boluses have not found clear evidence of behavioral hyposensitivity to repeated dopaminergic stimulation in Parkinson's disease (PD). Here we analyze that data, and review experimental findings in animal models and our previous experience with parkinsonian patients. We conclude that acute tolerance to pulsatile stimulation is likely to play a role in the pathophysiology of motor fluctuations in PD.     

Parkinson's disease: cell death mechanisms

Parkinson disease is a neurodegenerative disorder of aging characterized by a selective and progressive loss of dopaminergic neurons within the substantia nigra. The diagnosis of the disease is made when neuronal cell loss exceeds 50 p. cent indicating that the degenerative process started well before the onset of the first clinical symptoms. Three populations of dopaminergic neurons seem to coexist in the substantia nigra of parkinsonian patients; (1) senescent neurons that are still spared by the pathological process; (2) sick neurons exhibiting generally a preserved morphology but showing evidence of biochemical and metabolic abnormalities; (3) neurons which have entered into a final state of agony and exhibit the hallmarks of apoptosis, a controlled form of cell death that requires the activation of a particular type of proteases, caspases. In the inherited forms of the disease that are caused by mutations of genes encoding the Parkin, alpha-synuclein and UCHL-1 proteins, the degenerative process results from the dysfunction of an enzymatic complex of proteolysis, the proteasome. This probably leads to the intracellular accumulation of abnormal proteins that become deleterious for dopaminergic neurons. In the sporadic forms of the disease that are the most frequent, causes of the cell demise remain still unknown but neurodegeneration might also result from a decreased activity of the proteasome. A defect in the detoxification of reactive oxygen species or an energy failure caused by inhibition of the mitochondrial respiratory chain, at the complex I level, are other hypothesis that are frequently mentioned. Finally, activated glial cells (astrocytes and microglia) located around the degenerating dopaminergic neurons might also intervene in the mechanism of degeneration by perpetuating or even amplifying the primary neuronal insult. Proinflammatory cytokines acting on cell death membrane receptors and diffusable messengers such as nitric oxide could be part of this process.     

Quantification of the dopaminergic response in Parkinson's disease

BACKGROUND: Various investigators have developed complex quantitative procedures for objective assessment of parkinsonian motor impairment, since drawbacks of rating scales are interrater variability, subjective impression, insensitivity to subtle modifications. OBJECTIVES: To determine whether standardized performance of inserting pegs (i) differentiates between parkinsonian subjects and healthy controls and (ii) reflects quantification of the dopaminergic response with rating scales within a levodopa challenge test design. SUBJECTS AND METHODS: We used an easy-to-operate Purdue Pegboard-like apparatus, which measures the total time taken to insert 25 pegs from a rack into a series of appropriate holes by a computer to 100 ms accuracy, and simultaneous rating with part III of the Unified Parkinson's Disease Rating Scale for assessment of motor impairment in 28 idiopathic parkinsonian patients before and during a levodopa challenge test. Additionally we compared data of the instrumental task to age- and sex-matched healthy controls. RESULTS: We found significant differences between parkinsonian subjects and controls and significant correlations to the rated severity of Parkinson's disease. Within-subject comparisons and correlation analysis demonstrated the ability of this tool to reflect scored motor improvement after intake of levodopa. CONCLUSION: Inserting pegs provides an objective quantitative estimation of changes in motor impairment within a typical levodopa challenge test design.     

Challenge tests to predict the dopaminergic response in untreated Parkinson's disease

To clarify the predictive role of dopaminergic challenge tests, we compared the responses to subcutaneous apomorphine and oral levodopa with the therapeutic effect of ongoing levodopa treatment in 45 previously untreated patients with idiopathic Parkinson's disease. The response to long-term levodopa was accurately predicted by apomorphine in 67% (30) of patients and by levodopa in 80% (35) of patients. There were nine cases without a definite response to sustained levodopa, four in patients who developed atypical clinical features during the period of follow-up. These tests have a predictive value for subsequent dopaminergic responsiveness and may help in the early differential diagnosis of parkinsonian syndromes.     

Midbrain dopaminergic cell loss in Parkinson's disease: computer visualization

Computer visualization techniques were used to map the distribution of dopaminergic neurons within midbrain tissue sections from 5 parkinsonian patients and 3 age-matched control subjects. The Parkinsonian brains had over 50% fewer dopaminergic neurons within the midbrain than age-matched normal brains. The cell loss occurred within the combined substantia nigra (dopaminergic nucleus A9) and retrorubral (dopaminergic nucleus A8) areas (greater than 61%) and the ventral tegmental area (dopaminergic nucleus A10) (greater than 42%). The cell loss was greatest within the ventral portion of the substantia nigra zona compacta. The specific pattern of cell loss is very similar to the pattern of cells that project to the striatum (as opposed to cortical and limbic sites) in animal neuroanatomical tracing experiments. These data suggest that Parkinson's disease preferentially destroys midbrain dopaminergic neurons in nuclei A8, A9, and A10, which project to the striatum.     

罗格列酮通过抗凋亡机制保护帕金森病模型小鼠多巴胺神经元

目的研究罗格列酮在1-甲基-4-苯基-1,2,3,6四氢吡啶(MPTP)所致帕金森病(PD)模型小鼠中对多巴胺能神经元的保护作用。方法采用MPTP制备PD小鼠模型,观察各组小鼠行为学变化,免疫组织化学和免疫印迹法观察中脑黑质TH、caspase-9、caspase-6、Bcl-2和Bax的表达变化,TUNEL检测细胞凋亡情况,并观察给予罗格列酮后对上述变化的影响。结果模型组小鼠出现竖毛、翘尾、震颤、肌肉强直和运动变缓等PD样症状,黑质区TH阳性神经元缺失,并伴有Caspase-9、caspase-6、Bax高表达及TUNEL阳性细胞增加,而Bcl-2的表达与对照组相比下降;经罗格列酮处理后,上述情况得到一定程度逆转。结论罗格列酮可通过阻抑凋亡调控蛋白的异常表达,发挥对PD模型小鼠多巴胺能神经元保护作用。     

Factors predicting response to dopaminergic treatment for resting tremor of Parkinson's disease

We aimed to evaluate the clinical factors predicting response to dopaminergic treatment for resting tremor in patients with Parkinson's disease (PD). Eighty‐five PD patients with prominent resting tremor, defined as tremors of score greater than 3 in at least one limb on the Unified Parkinson's Disease Rating Scale (UPDRS), were divided into those responsive or nonresponsive to dopaminergic treatment. Responsiveness was defined as a reduction of at least two points for more than 3 months in the UPDRS tremor score. Of the 85 patients, 36 (42.4%) were responsive and 49 (57.6%) were nonresponsive to dopaminergic treatment. Initial UPDRS III score (P = 0.015) and Hoehn and Yahr stage (P = 0.010) were each significantly higher in the RG than in the NRG. UPDRS subscores for rigidity (P = 0.012), bradykinesia (P = 0.021) and postural impairment (P = 0.018) also correlated with responsiveness to dopaminergic treatment. Resting tremor in PD patients was more responsive to dopaminergic treatment when accompanied by moderate degrees of bradykinesia and rigidity than in patients without other prominent parkinsonian features. © 2007 Movement Disorder Society     

Pathogenesis of nigral cell death in Parkinson's disease

Parkinson's disease (PD) is primarily a sporadic condition which results mainly from the death of dopaminergic neurons in the substantia nigra. Its etiology remains enigmatic while its pathogenesis begins to be understood as a multifactorial cascade of deleterious factors. As of yet, most insights into PD pathogenesis are derived from toxic models of PD and show that the earlier cellular perturbations arising in dopaminergic neurons include oxidative stress and energy crisis. These alterations, rather than killing neurons, trigger subsequent death-related molecular pathways including elements of apoptosis. The fate of dopaminergic neurons in PD may also be influenced by additional factors such as excitotoxicity, emanating from the increased glutamatergic input from the subthalamic nucleus to the substantia nigra, and the glial response that arises in the striatum and the substantia nigra. In rare instances, PD can be familial, and those genetic forms have also provided clues to the pathogenesis of nigrostriatal dopaminergic neuron death including abnormalities in the mechanisms of protein folding and degradation as well as mitochondrial function. Although more remains to be elucidated about the pathogenic cascade in PD, the compilation of all of the aforementioned alterations starts to shed light on why and how nigral dopaminergic neurons may degenerate in this prominent disease, that is PD.     

Continuous subcutaneous infusion of pramipexole protects against lipopolysaccharide-induced dopaminergic cell death without affecting the inflammatory response

The D2/D3 dopamine receptor agonist pramipexole, protects against toxin-induced dopaminergic neuronal destruction but its mechanism of action is unknown. Inflammation following glial cell activation contributes to cell death in Parkinson's disease and we now report on the effects of acute or chronic administration of pramipexole on lipopolysaccharide (LPS) induced inflammation and nigral dopaminergic cell death in the rat. At 48 h and 30 days following supranigral administration of LPS, approximately 70% of tyrosine hydroxylase (TH) immunoreactive (-ir) cells in substantia nigra had degenerated with a corresponding loss of TH-ir terminals in the striatum. In rats acutely treated with pramipexole (2 × 1 mg/kg; s.c.) 48 h following LPS application, there was no difference in the number of TH-ir cells or terminals compared to LPS-treated rats receiving vehicle. However, the continuous subcutaneous infusion of pramipexole for 7 days prior to LPS and 21 days subsequently, produced a marked preservation of both TH-ir cells and terminals. At 48 h or 30 days, LPS induced an up-regulation of ubiquitin-ir within the nigral TH-ir neurones, which was reduced by pramipexole treatment. Thirty days following supranigral LPS administration (9 days after the end of infusion), (+)-amphetamine (5 mg/kg, i.p.) caused robust ipsiversive rotation. In rats treated with LPS but receiving continuous subcutaneous administration of pramipexole, (+)-amphetamine-induced rotation was markedly reduced. LPS-induced increase in the levels of inflammatory markers, were not affected by either acute administration or continuous infusion of pramipexole. Continuous infusion of pramipexole protected dopaminergic neurones against inflammation induced degeneration but without modification of the inflammatory response.     

Pathological gambling secondary to dopaminergic therapy in Parkinson's disease

We describe six patients with Parkinson's disease (PD) and pathological gambling. All patients started gambling after the onset of PD and initiation or increase of treatment with dopaminergic therapy. The fact that pathological behaviour disappeared as medication was ended or decreased suggests that an elaborate behavioural manifestation could be related to dopamine tone in patients with Parkinson's disease.     

Evidence for long-term survival and function of dopaminergic grafts in progressive Parkinson's disease

Two patients with idiopathic Parkinson's disease (Patients 3 and 4 in our series) were followed up to 3 years after grafting of human embryonic dopamine-rich mesencephalic tissue unilaterally into the putamen. During the first postoperative year both patients showed significant amelioration of parkinsonian symptoms and increased 6-L -[¹⁸F]-fluorodopa uptake in the grafted putamen, as assessed with positron emission tomography. Three years after grafting the patients still exhibited increased fluorodopa uptake in the grafted putamen and significant clinical improvements, evidenced by a reduction of the severity of symptoms and of the time spent in the “off” phase, and by a prolongation of the effect of a single dose of L -dopa. Between 1 and 3 years after surgery, Patient 3 showed only minor changes of parkinsonian symptoms on the side contralateral to the graft, whereas there was a worsening on the ipsilateral side. Fluorodopa uptake decreased in the nongrafted putamen but was unchanged in the grafted putamen. Patient 4 continued to improve after the first postoperative year and L -dopa was withdrawn after 32 months. The reduction of parkinsonian symptoms on the side contralateral to the graft became more pronounced between 1 and 3 years after surgery. Fluorodopa uptake further increased in the grafted putamen, whereas no change was detected on the non-grafted side. These results indicate that grafts of embryonic dopamine neurons can survive, grow, and exert functional effects up to at least 3 years after surgery in the parkinsonian brain, despite an ongoing disease process leading to degeneration of the intrinsic dopamine system.     

Evidence linking neuronal cell death to autoimmunity in Alzheimer's disease

The catastrophic loss of cerebral neurons in Alzheimer's disease (AD) is not fully understood. Since serum proteins are known to extravasate into the brain parenchyma in AD due to blood-brain barrier (BBB) dysfunction, this study was designed to explore the possibility that neuronal cell death may be the consequence of the anomalous presence of serum proteins in the brain. As compared to age-matched, non-demented 'control' brain tissues, highly significant increases of immunoglobulins (Igs) were detected in parenchyma, which were associated with vessels in the AD brain tissues. Also, there were dramatic increases of +Ig-neurons in areas with greater parenchymal Ig reactivity. The Ig labeling extended throughout the cell, which showed neurodegenerative apoptotic features that were not observed in -Ig-neurons. Thus, the presence of +Ig-neurons in AD brains implies a critical link between the faulty BBB and neuronal death through an autoimmune mechanism.     

Differential response of speed, amplitude, and rhythm to dopaminergic medications in Parkinson's disease

Although movement impairment in Parkinson's disease includes slowness (bradykinesia), decreased amplitude (hypokinesia), and dysrhythmia, clinicians are instructed to rate them in a combined 0–4 severity scale using the Unified Parkinson's Disease Rating Scale motor subscale. The objective was to evaluate whether bradykinesia, hypokinesia, and dysrhythmia are associated with differential motor impairment and response to dopaminergic medications in patients with Parkinson's disease. Eighty five Parkinson's disease patients performed finger‐tapping (item 23), hand‐grasping (item 24), and pronation–supination (item 25) tasks OFF and ON medication while wearing motion sensors on the most affected hand. Speed, amplitude, and rhythm were rated using the Modified Bradykinesia Rating Scale. Quantitative variables representing speed (root mean square angular velocity), amplitude (excursion angle), and rhythm (coefficient of variation) were extracted from kinematic data. Fatigue was measured as decrements in speed and amplitude during the last 5 seconds compared with the first 5 seconds of movement. Amplitude impairments were worse and more prevalent than speed or rhythm impairments across all tasks (P < .001); however, in the ON state, speed scores improved exclusively by clinical (P < 10^?6) and predominantly by quantitative (P < .05) measures. Motor scores from OFF to ON improved in subjects who were strictly bradykinetic (P < .01) and both bradykinetic and hypokinetic (P < 10^?6), but not in those strictly hypokinetic. Fatigue in speed and amplitude was not improved by medication. Hypokinesia is more prevalent than bradykinesia, but dopaminergic medications predominantly improve the latter. Parkinson's disease patients may show different degrees of impairment in these movement components, which deserve separate measurement in research studies. © 2011 Movement Disorder Society     

Cortical response to levodopa in Parkinson's disease patients with dyskinesias

Levodopa‐induced dyskinesias are a common and disabling side effect of dopaminergic therapy in Parkinson's disease, but their neural mechanisms in vivo are still poorly understood. Besides striatal pathology, the importance of cortical dysfunction has been increasingly recognized. The supplementary motor area in particular, may have a relevant role in dyskinesias onset given its involvement in endogenously generated actions. The aim of the present study was to investigate the levodopa‐related cortical excitability changes along with the emergence of levodopa‐induced peak‐of‐dose dyskinesias in subjects with Parkinson's disease. Thirteen patients without dyskinesias and ten with dyskinesias received 200/50 mg fast‐acting oral levodopa/benserazide following overnight withdrawal (12 hr) from their dopaminergic medication. We targeted transcranial magnetic stimulation to the supplementary motor area, ipsilateral to the most dopamine‐depleted striatum defined with single‐photon emission computed tomography with [¹²³I]N‐ω‐fluoropropyl‐2β‐carbomethoxy‐3β‐(4‐iodophenyl)nortropane, and recorded transcranial magnetic stimulation‐evoked potentials with high‐density electroencephalography before and at 30, 60, and 180 min after levodopa/benserazide intake. Clinical improvement from levodopa/benserazide paralleled the increase in cortical excitability in both groups. Subjects with dyskinesias showed higher fluctuation of cortical excitability in comparison to non‐dyskinetic patients, possibly reflecting dyskinetic movements. Together with endogenous brain oscillation, levodopa‐related dynamics of brain state could influence the therapeutic response of neuromodulatory interventions.     

H reflex threshold in Parkinson's disease patients for different stimulus duration

Electrical stimulus, with duration starting at 0.1 ms and gradually increased to 1.0 ms, was used for eliciting the H reflex in 14 normal subjects and 19 patients with Parkinson's disease (PD). In 71.1% of normal subjects and in 13.2% of PD patients the H reflex to M response threshold ratio (H/M TR) was <1 and the H reflex was obtained before the M response for all duration stimuli. For all stimulus durations a significant difference between the H/M TR in normal subjects and PD patients was found (t test 0.002-0.007). The duration effect was found to be highly significant-H/M TR for short stimulus duration was greater than for long stimulus durations (p<0.001). The optimal stimulus duration for evaluating H reflex behavior in PD patient was 0.2 ms.These very significant differences in behavior of the H reflex in PD patients could be used as another parameter in the assessment of extrapyramidal rigidity in PD patients.