L’olfaction chez le patient gériatrique : constantes et spécificités pathologiques des interactions olfacto-trigéminales dans une population porteuse de synucléopathies / Olfaction in elderly : constants and pathological characteristics of the olfactory and trigeminal interactions in a population carrying synucleopathies

Foguem, Clovis

19 December 2017

CONTEXTE: La maladie de Parkinson idiopathique (MPI), la démence à corps de Lewy (DCL) et la démence parkinsonienne (DP) sont des synucléinopathies. La dysfonction olfactive est reconnue comme étant une caractéristique principale de ces maladies. L'objectif de ce travail était d'évaluer et de comparer les seuils de détection olfactifs dans ces trois synucléinopathies (MPI, DP, DCL) chez des sujets âgés de plus de 65ans. Dans cette optique, trois études ont été menées utilisant des substances odorantes stimulant variablement les systèmes trigéminal et olfactif.MÉTHODES: les tests de détection des seuils olfactifs ont été réalisés chez (1) 89 patients ayant une MPI versus témoins sains, (2) 17 PD versus MPI et (3) 20 DCL versus PD versus témoins sains appariés, en utilisant l'alcool phényléthylique, le n-butanol et la pyridine comme stimuli. Les seuils de détection de ces 3 odorants ont été évalués à l'aide d'une série de dilution de facteur 2 et une procédure ascendante de choix forcé.Les données ont été analysées en utilisant des tests de Mann-Whitney-Wilcoxon ou Kruskal-Wallis, la corrélation de Spearman et des analyses de covariance. Des analyses discriminantes ont également été réalisées.RÉSULTATS: (1) Les seuils de détection olfactifs sont capables de discriminer les patients MPI des témoins sains et les patients ayant une MPI bénigne de ceux avec autonomie déficiente. De plus, nous avons trouvé une subtile interaction entre les systèmes olfacto-trigeminal.(2) Nos résultats mettent en évidence, une absence de différence significative des seuils de détection des odorants entre MPI et PD appariés.(3) Nous avons constaté des différences significatives des seuils olfactifs entre patients ayant une DCL, une DP et témoins sains (p <0,001), avec une altération majeure de la sensibilité olfactive chez les patients atteints de DCL par rapport à ceux ayant une DP.Au travers des 3 études, une corrélation significative a été trouvée entre les seuils de détection des trois odorants.CONCLUSION: Ce travail souligne que la DCL peut être distinguée de la DP, la DP des sujets sains et la MPI des sujets sains en évaluant les seuils de détection des trois odorants. Cependant, l’absence de différence significative entre les seuils de détection olfactifs entre les MPI et DP soulève des doutes sur l'importance des tests de seuils de détection olfactive dans le suivi cognitif dans la MPI. D'autres recherches sur le dysfonctionnement olfactif dans les synucléinopathies sont nécessaires pour conforter nos résultats.MOTS CLÉS: Principales synucléinopathies (maladie Parkinson idiopathique, Démence parkinsonienne, Démence à corps de Lewy); seuils de détection des odorants; interactions des systèmes olfacto-trigéminal ; diagnostics positif et différentiel. / Idiopathic Parkinson disease (IPD), Dementia with Lewy bodies (DLB) and Parkinson’s disease dementia (PDD) are synucleinopathies. Olfactory impairment is recognized as a characteristic feature of some synucleinopathies. The aim of this study was to assess and compare olfactory detection thresholds in these three synucleinopathies (IPD, PDD and DLB). For that purpose three studies were conducted: (1) Elderly with IPD matched to healthy controls, (2) IPD versus PPD and (3) between DLB, PDD and healthy controls using odor stimuli that variably trigger nasal trigeminal and olfactory systems.METHODS: Olfactory thresholds tests were performed in 89 IPD patients aged over 65 compared to paired matched healthy controls, in 17 IPD versus and matched PDD patients and in 20 LDB patients versus PDD patients versus matched healthy controls, using Phenyl-ethyl alcohol, n-Butanol and Pyridine as stimuli. Detection thresholds for these 3 odorants were assessed using an ascending staircase factor-2 odor dilutions series and a binary forced-choice procedure. Participants were priory evaluated by experimented physicians.Data were analyzed using Mann-Whitney-Wilcoxon or Kruskal-Wallis tests, Spearman correlation and covariance analyses. Discriminant analyses were also carried out to predict and classify the three participants’ groups in the third study.RESULTS: (1) Olfactory detection thresholds are able to discriminate elderly IPD from healthy controls, with a fair detection thresholds performance for pyridine compared to the two other odorants; and the ability to distinguish benign IPD patients with good autonomy from those with impaired autonomy (malign IPD). Moreover, we found subtle olfacto-trigeminal systems interaction.(2) Our results highlight no significant difference on odor detection threshold between elderly IPD compared with matched PDD patients.(3) We found significant odor thresholds differences between LBD patients, PDD patients and healthy controls (all p-values < 0.001), with also a significant poor sense of smell in DLB patients compared to moderate PDD patients. A plain differentiation between the three groups was confirmed by standardized canonical discriminant analyses.Through the 3 studies, a significant correlation was found between the odor detection thresholds.CONCLUSION: This work highlights that DLB can be distinguished from PDD, PDD from healthy controls and IPD from healthy controls by assessing odors (PEA, n-butanol, pyridine) detection thresholds. However, the lack of difference between olfactory thresholds between IPD and PDD raises doubts on the importance of olfactory thresholds tests in the cognitive follow-up of patients with IPD.Further investigations of olfactory dysfunction in patients with synucleinopathies are needed to confirm our results.KEYWORDS: idiopathic Parkinson disease; Parkinson's disease dementia ; Dementia with Lewy bodies; odor detection thresholds; chemonasal trigeminal and olfactory systems interactions; clinical diagnosis.

Olfaction

Peronnes âgées

Interactions olfacto-Trigéminales

Synucléinopathies

Trijumeau

Maladie de Parkinson

Olfaction

Elderly

Olfactory and trigeminal interactions

Synucleopathies

Trigeminal system

Parkinson disease

616.8

MOLECULAR PERTURBATIONS IN SYNUCLEINOPATHY DISORDERS: INSIGHTS FROM PRE-CLINICAL TO HUMAN NEUROPATHOLOGY

Paola C. Montenegro (5930060)

15 May 2019

<div><p>Parkinson’s disease (PD) is a devastating neurodegenerative disorder that affects 10 million people worldwide and is characterized by pronounced motor symptoms. Dementia with Lewy Bodies (DLB) involves both cognitive and motor deficits and affects ~1 million people in the United States. To date there is no cure for PD or DLB, and current treatments address only a subset of the symptoms that define these diseases. PD and DLB are ‘synucleinopathies’, defined as disorders involving the accumulation in patients’ brains of Lewy bodies. Lewy bodies are cellular inclusions that consist largely of aggregated species of alpha-synuclein (aSyn), a presynaptic protein that exists as both cytosolic and membrane-bound forms. Pathophysiological findings suggest that aggregated aSyn is involved in neurodegeneration in PD and DLB. However, mechanisms by which aSyn forms neurotoxic aggregates, and neurotoxic processes that distinguish different synucleinopathies such as PD and DLB, are poorly understood. To address these gaps, we have (i) designed a protocol to establish a primary cell culture model that can recapitulate key neuropathological features of PD, (ii) examined effects of expressing aSyn variants in a rat model of PD, and (iii) examined the expression profiles of neuroprotective genes in PD and DLB brain specimens.</p><p> </p><p>In the first part of my thesis, I describe the development of an optimized protocol to prepare primary midbrain and cortical cultures from rat embryonic brains for the study of PD and other synucleinopathies. The establishment of cellular models that simulate specific aspects of neuropathology can enable the characterization of molecular perturbations that lead to dopaminergic (DA) neuronal death. Our primary midbrain mixed culture model provides an outstanding opportunity to explore therapeutic strategies to rescue DA neurons from toxicity elicited by a range of PD-related insults. In addition, our primary cortical mixed cultures can be used to model cortical neuropathology in various CNS disorders including synucleinopathies.</p><p> </p><p>A number of mutations in the gene that codes for aSyn are associated with familial, early-onset forms of PD. A major goal of my thesis research is to characterize neurotoxic effects of a recently discovered familial substitution, A53E. This mutant was chosen based on the rationale that the introduction of a negatively charged residue at position 53 could potentially interfere with aSyn-membrane interactions and favor A53E aggregation, as we described for other familial aSyn mutants. For the first time, we have reproduced the neurotoxicity of A53E seen in human patients by expressing the mutant protein in rat midbrain. Rats injected unilaterally in the substantia nigra (SN) with rAAV encoding A53E and another familial mutant, A53T, but not rAAV encoding WT aSyn or a vector-control (‘stuffer’) virus, exhibited a significant motor impairment. Immunohistochemical analysis at 14 weeks after the viral injection revealed that brain sections from aSyn-expressing rats exhibit key features reminiscent of neuropathology in human PD, including nigral dopaminergic neuron loss (confirmed by unbiased stereology), striatal terminal depletion, and aSyn inclusion formation. In addition, it was determined that WT aSyn and the A53E and A53T mutants invaded the non-injected substantia nigra, implying that expressed aSyn protein can spread throughout the brain in the rat rAAV-aSyn model. These results yield insights into the molecular basis for the neurotoxicity of A53E and shed light on a potential role for membrane-induced aSyn aggregation in PD pathogenesis in vivo, thus setting the stage for developing therapies to slow neurodegeneration in the brains of familial and idiopathic PD patients. </p><p> </p><p>aSyn neurotoxicity varies with the expression of neuroprotective proteins, and misfolded aSyn affects cellular functions and gene expression. These observations suggest that differential gene expression patterns can inform us about similarities and differences in pathogenic mechanisms of different synucleinopathy disorders. A third phase of my thesis research was aimed at determining the expression levels of a panel of candidate neuroprotective genes in post-mortem brain samples from DLB and PD patients and age-matched controls (5 individuals in each group). mRNAs encoding the following proteins were quantified via qRT-PCR in homogenates prepared from the frontal cortex and the BA24 region encompassing the cingulate gyrus: DJ-1, a protein with antioxidant and chaperone activities; PGC1α, a master regulator of mitochondrial biogenesis and oxidative metabolism; MsrA, an antioxidant enzyme responsible for repairing oxidatively damaged proteins; and ATP13A2, a lysosomal protein involved in autophagy. In addition to yielding new insights into differential gene expression patterns in cortex versus cingulate gyrus, the data revealed differences in mRNA expression levels in DLB versus non-DLB cortical tissue. Although levels of all four neuroprotective mRNAs were increased (or showed a trend towards being increased) in DLB cortex, Western blot analysis revealed that only the DJ-1 and PGC1α proteins showed a trend towards being up-regulated, whereas levels of ATP13A2 and MsrA were unchanged. These findings suggest that there is a failure to induce cellular antioxidant responses and lysosomal autophagy at the protein level in DLB cortex, and in turn this failure could contribute to neuropathology. Interestingly, analysis of the same panel of neuroprotective genes in PD cortical samples did not show significant differences in mRNA or protein levels compared to control samples, suggesting that different neuroprotective mechanisms are induced in DLB versus PD cortex. These studies shed light on brain-region specific changes in gene expression associated with different synucleinopathy disorders, and they set the stage for developing new diagnostic tests and therapeutic strategies.</p></div><br>

Diseases

Cellular Nervous System

Central Nervous System

Neurosciences not elsewhere classified

Synucleopathies

Parkinson's disease

Dementia with Lewy bodies (DLB)

alpha-synuclein toxicity

dopaminergic neurons loss

striatal terminals

neuroprotection.