Analýza vybraných mitochondriálních proteinů ve svalové tkáni prasečího modelu Huntingtonovy choroby / Protein analysis of selected mitochondrial proteins in the muscle tissue of porcine model of Huntington's disease

Dosoudilová, Žaneta

January 2016

Huntington's disease (HD) is an autosomal dominant hereditary neurodegenerative disease characterized by motor, cognitive and behavioral disorders. HD is caused by expansion of CAG triplet (cytosine-adenosine-guanine) located in a gene on the short arm of the fourth chromosome. This expansion encodes an aberrant polyglutamine chain in the protein huntingtin. Physiological and mutated huntingtin (in case of HD) are expressed in almost all tissues and influences many cellular functions. The prevalence of HD in population is about 1 per 10.000. The disease is currently incurable and its mechanisms are not sufficiently understood. Besides affecting the central nervous system HD also affects peripheral tissues, including skeletal muscles. HD disrupts mitochondrial function and damages oxidative phosphorylation system, which has the task of producing energy in the form of ATP in cells. Research of transgenic minipig model for HD could help elucidate the mechanisms of disease's pathogenesis and potential therapeutic strategy. In this diploma thesis, immunodetection with help of specific antibodies to detect changes in amount of 14 selected mitochondrial proteins in skeletal muscle tissue of three age groups of transgenic HD minipigs - 24, 36 and 48 months old was used. Gradual progression in reduced...

Prasečí modely pro Huntingtonovu chorobu / Porcine models for Huntington disease

Růna Vochozková, Petra

January 2019

The causative role of the huntingtin (HTT) gene in Huntington's disease (HD) has been identified more than 25 years ago. The extension of CAG repeat stretch over 39 repeats in exon 1 of one HTT allele results in full penetrance of this neurodegenerative disorder. While the identification of the causative mutation raised hopes that development of the therapeutic compound will be easily achievable, the patients and their families are still waiting for treatment until now. The main reason for that might be the complex cellular function HTT that makes the determination of the pathologic mechanism difficult and the development of treatments even more challenging. Although a lot of different animal models have been generated until now, establishing a suitable model has still not been achieved yet. Due to its anatomy, physiology, and genetics, the minipig seems to be a suitable candidate for neurodegenerative disease models. Indeed, the existing Transgenic (Tg) Libechov minipig model manifests signs typical for HD in patients, but on the other hand significant inconsistencies have also been observed. The finding of malformation that partially shows the situation in human patients is true for both, the male reproductive tract as well as for the brain. The reason for this might be the fact the genetic...

CRMP1 protein complexes modulate polyQ-mediated Htt aggregation and toxicity in neurons

Bounab, Yacine

25 August 2010

Chorea Huntington (HD) ist eine neurodegenerative Erkrankung, die durch Ablagerungen von N-terminal Polyglutamin-reichen Huntingtin (Htt) -Fragmenten in den betroffenen Neuronen charakterisiert ist. Das mutierte Htt (mHtt) Protein wird ubiquitär exprimiert. Das zellspezifische Absterben von „medium-sized spiny neurons“ (MSN) wird jedoch im Striatum von HD Patienten verursacht (Albin, 1995). Es wird angenommen, dass Striatum-spezifische Proteine, die mit Htt interagieren, eine wichtige Rolle in der Pathogenese von HD spielen (Ross, 1995). Protein-Protein-Interaktionsstudien haben gezeigt, dass einige der Htt-Interaktionspartner mit unlöslichen Htt-Ablagerungen in den Gehirnen von HD-Patienten kolokalisieren und die Bildung von Protein-Aggregaten beeinflussen (Goehler, 2004). Kürzlich wurde durch die Integration von Genexpressions- und Interaktionsdaten ein Striatum-spezifisches Protein-Interaktionsnetzwerk erstellt (Chaurasia, unveröffentlichte Daten). Eines der identifizierten Proteine ist CRMP1 (collapsin response mediator protein 1), das spezifisch in Neuronen exprimiert wird und möglicherweise eine wichtige Rolle bei der Pathogenese von HD spielt. Experimentelle Untersuchungen mithilfe eines Filter-Retardationsassays zeigten, dass CRMP1 die Anordnung von Htt zu fibrillären, SDS-unlöslichen Aggregaten verringert. Durch Rasterkraftmikroskopie wurde der direkte Effekt von CRMP1 auf den Aggregationsprozess von Htt bestätigt. Ko-Immunopräzipitationsstudien zeigten, dass CRMP1 und Htt in Säugerzellen unter physiologischen Bedingungen miteinander interagieren. Es wurde nachgewiesen, dass CRMP1 die Polyglutamin-abhängige Aggregation und Toxizität von Htt in Zell- und Drosophila-Modellen von HD moduliert. Außerdem konnte CRMP1 in neuronalen Ablagerungen in R6/2 Mäusegehirnen und dessen selektive Spaltung durch Calpaine gezeigt werden. Diese Ergebnisse deuten darauf hin, dass die Lokalisation und Funktion von CRMP1 bei der Krankheitsentstehung verändert werden. / Huntington’s disease (HD) is a neurodegenerative disorder characterized by the accumulation of N-terminal polyglutamine (polyQ)-containing huntingtin (Htt) fragments in affected neurons. The mutant Htt (mHtt) protein is ubiquitously expressed but causes specific dysfunction and death of striatal medium-sized spiny neurons (MSNs) (Albin, 1995). It is assumed that striatum specific proteins interacting with Htt might play an important role in HD pathogenesis (Ross, 1995). Previous protein-protein interaction (PPI) studies demonstrated that many Htt-interacting proteins colocalize with insoluble Htt inclusions in HD brains and modulate the mHtt phenotype (Goehler 2004). A striatum-specific, dysregulated PPI network has been created recently by integrating PPI networks with information from gene expression profiling data (Chaurasia, unpublished data). One of the identified dysregulated proteins potentially involved in HD pathogenesis was the neuron-specific collapsin response-mediator protein 1 (CRMP1). Here, I show that CRMP1 reduces the self-assembly of SDS-insoluble mHtt protein aggregates in vitro, indicating a direct role of CRMP1 on the mHtt aggregation process. Coimmunoprecipitation studies showed that CRMP1 and Htt associate in mammalian cells under physiological conditions. In addition, CRMP1 localizes to abnormal neuronal inclusions and efficiently modulates polyQ-mediated Htt aggregation and toxicity in cell and Drosophila models of HD. This suggests that dysfunction of the protein is crucial for disease pathogenesis. Finally, I observed that CRMP1 localizes to neuronal inclusions and is selectively cleaved by calpains in R6/2 mouse brains, indicating that its distribution and function are altered in pathogenesis. In conclusion, this study presents new findings on the function of CRMP1 and its role in the pathogenesis of HD. The protein interacts with Htt and modulates its aggregation and toxicity, in this way influencing the molecular course of the disease.

Aggregation

Neurodegenerative Erkrankung

Chorea Huntington (HD)

Mutierte Huntingtin (mHtt)

Polyglutamin

Zytotoxizität.

Protein-Protein-Interaktionsnetzwerk

Aggregation

Neurodegenerative disorders

Huntington’s disease (HD)

Mutant Huntingtin (mHtt)

Polyglutamine

570 Biologie

32 Biologie

YC 7500

YG 5500

ddc:570

How the manipulation of the Ras homolog enriched in striatum alters the behavioral and molecular progression of Huntington’s disease

Lee, Franklin A

18 December 2015

Huntington’s disease is an incurable, progressive neurological disorder characterized by loss of motor control, psychiatric dysfunction, and eventual dystonia leading to death. Despite the fact that this disorder is caused by a mutation in one single gene, there is no cure. The mutant Huntingtin (mHtt) protein is expressed ubiquitously throughout the brain but frank cell death is limited to the striatum. Recent work has suggested that Rhes, Ras homolog enriched in striatum, which is selectively expressed in the striatum, may play a role in Huntington’s disease neuropathology. In vitro studies have shown Rhes to be an E3 ligase for the post-translational modification protein SUMO. Rhes increases binding of SUMO to mHtt which competes for the same binding site as Ubiquitin. SUMOylation of mHtt leads to disaggregation and cellular death, whereas ubiquitination leads to aggregation and cellular protection. In a previous study we showed that deletion of Rhes caused a decrease in the Huntington’s disease phenotype in mice. We hypothesized that mice lacking Rhes would also show increased aggregation in the striatum and this increased aggregation would correlate in a rescue of behavioral symptoms. Despite the prior in vitro and in vivo evidence, deletion of Rhes in vivo did not alter the aggregation of mHtt in the striatum of mice however deletion of Rhes still showed a rescue from the diseased phenotype. This result would indicate that deletion of Rhes alters the neurobehavioral phenotype of Huntington’s disease through a different pathway than promoting aggregation in striatal cells.

Rhes

RasD2

Huntington’s Disease

Huntingtin

mHtt

aggregate

Amino Acids, Peptides, and Proteins

Genetic Processes

Medical Anatomy

Medical Biochemistry

Medical Cell Biology

Medical Genetics

Medical Molecular Biology

Medical Neurobiology

Nervous System

Neurosciences

Binding and internalization of exogenous protein assemblies by mammalian cells / Liaison et internalisation d’assemblages protéiques exogènes par des cellules de mammifère

Ruiz Arlandis, Gemma

13 March 2015

Le mépliement et l'agrégation des protéines sont à l'origine de nombreuses maladies neurodégénératives, dont la maladie de Huntington (HD) et la maladie de Parkinson (PD). Même si l’agrégation de différentes protéines liées à des maladies est bien documentée, on en sait peu sur l'interaction entre les protéines mal repliées et les cellules neuronales, qui leur permettent de se propager et affecter différentes régions du cerveau. L'objectif de ma thèse était de générer des modèles cellulaires rapporteurs de la huntingtine et l’α-synucléine, protéines dont le mauvais repliement et l'agrégation sont à l'origine de HD et PD respectivement, et utiliser ces modèles cellulaires pour étudier les interactions entre les agrégats et des lignées cellulaires de mammifères. Notre but c’était de documenter les propriétés de liaison et d’absorption de ces agrégats par les cellules rapporteuses, et les conséquences de leur internalisation pour les cellules. Deux modèles cellulaires de neuroblastome (SH-SY5Y et Neuro2A) et un modèle de cellules d’ostéoblastome (U2OS) exprimant la protéine fluorescente ChFP ont été générés pour HD. Pour simuler ce qui se passe au sein de neurones réels, des cellules de neuroblastome ont été induites à se différencier. Des différences de fixation, internalisation, nucléation de la protéine endogène et localisation finale des agrégats de polyglutamine internalisés ont été observées entre les cellules différenciées et non différenciées. Des cellules rapporteuses U2OS ont été utilisées pour déterminer les différences d’infectiosité entre des fibres de HttExon1 assemblés en présence ou en l’absence de la protéine de choc thermique constitutivement exprimée chez l'Homme Hsc70. Hsc70 a un effet protecteur car il rend les fibres moins infectieuses pour les cellules de mammifères en culture. Enfin, un modèle cellulaire de neuroblastome (Neuro2A) rapporteur pour PD exprimant l’α-synucléine fusionnée à la protéine ChFP a été utilisé pour déterminer des différences de liaison, pénétration, absorption, nucléation de la protéine endogène et persistance entre deux polymorphismes d’α-synucléine générés par notre équipe. L'hétérogénéité observée dans différents patients souffrant de synucléinopaties pourrait s'expliquer par différents polymorphes d’assemblages protéiques d’α-synucléine présents dans les cerveaux des malades, ce qui doit être pris en compte pour les développements thérapeutiques futurs.Ces modèles cellulaires rapporteurs pour différentes maladies sont un système valable pour l'étude de différents processus cellulaires liés à l'interaction entre les protéines agrégées exogènes et des cellules de mammifères en culture. Nos résultats indiquent un mécanisme commun par lequel les différentes protéines agrégées peuvent interagir avec des cellules en culture: les protéines mal repliées exogènes sont capables de se lier à des membranes cellulaires, les pénétrer, entrer dans l'espace intracellulaire et recruter des protéines endogènes solubles. Même si cela semble être un mécanisme générique pour des protéines infectieuses telles que la α-synucléine ou la huntingtine, des lignées cellulaires avec différents phénotypes montrent différences de vulnérabilité à la présence de protéines agrégées. Ceci suggère la présence de récepteurs spécifiques à la surface de la cellule capables de reconnaître des structures de type amyloïde. D'autres études sont nécessaires pour déterminer la nature de ces récepteurs et si sa modulation pourrait être utile pour contrôler la propagation des ces maladies dans le cerveau. / Protein misfolding and aggregation are at the origin of many neurodegenerative diseases, including Huntington’s disease (HD) and Parkinson’s disease (PD). Even if the aggregation of different disease-related proteins is well documented, little is known about the interaction between those misfolded proteins and neuronal cells that allow them to spread and affect several regions of the brain. The objective of my thesis was to generate reporter cellular models of huntingtin and α-synuclein, proteins whose misfolding and aggregation are at the origin of HD and PD respectively, and use these cell models for studying the interactions between misfolded protein aggregates and mammalian cell lines. We aimed to document the binding and uptake properties of those aggregates by reporter cells and the consequences of their internalization for the cells. Two neuroblastoma cell models (SH-SY5Y and Neuro2A) and an osteoblastoma cell model (U2OS) expressing the fluorescent protein ChFP were generated as mammalian reporter cell lines for HD. To mimic what happens in real neurons, neuroblastoma reporter cells were induced to differentiate. Differences in binding, internalization, nucleation of the endogenous protein and final localization of the internalized polyglutamine aggregates were observed between differentiated and undifferentiated cells. U2OS reporter cells were used for determining differences in the infectivity of HttExon1 fibrils assembled in the presence or in the absence of the constitutively expressed heat shock protein Hsc70, suggesting a protective effect of Hsc70, since it renders the fibrils less infectious to mammalian cells. Finally, a neuroblastoma reporter cell model (Neuro2A) of PD expressing α-synuclein fused to the fluorescent and reporter protein ChFP was used to determine the different binding, penetration, uptake, nucleation of the endogenous protein and persistence properties of two α-synuclein polymorphs generated by our team. The heterogeneity observed in different patients suffering from synucleinopathies could be explained due to different α-synuclein assemblies present in diseased brains, what needs to be taken into account for future therapeutic developments. These reporter cellular models for different diseases are a valid system for the study of different cellular processes related with the interaction between exogenous aggregated proteins and mammalian cells in culture. Our results indicate a common mechanism by which different aggregated proteins can interact with cells in culture: exogenous misfolded proteins are able to bind cell membranes, penetrate them, enter the intracellular space and recruit endogenous soluble proteins. Even if this seems to be a generic mechanism for infectious proteins such as α-synuclein or huntingtin, different cell lines or cell phenotypes show distinct vulnerability to the presence of aggregated proteins. This strongly suggests the presence of specific receptors at the surface of the cell able to recognize amyloid-like structures. Further investigations are needed to determine the nature of these receptors and whether their modulation might be helpful for controlling the spread of these diseases within the brain.

Maladie de Huntington

Maladie de Parkinson

Agrégats protéiques

Huntingtine

Α-synucléine

Hsc70

Cellules rapporteuses

Liaison

Internalisation

Mépliement des protéines

Huntington’s disease

Parkinson’s disease

Protein aggregates

Huntingtin

Α-synuclein

Hsc70

Reporter cell lines

Binding

Internalization

Protein misfolding

Altered Skeletal Muscle Excitation-Contraction Coupling in the R6/2 Transgenic Mouse Model for Huntington's Disease

Miranda, Daniel R.

January 2021

No description available.

Biomedical Research

Biology

Physiology

action potential

duration

prolonged

calcium

Ca2+

force

excitation-contraction coupling

EC coupling

chloride

potassium

Cl-

K+

inwardly rectifying

Kir

ClC-1

skeletal muscle

Huntington's disease

huntingtin

release

flux

voltage

gated

KV

KV1.5

KV3.4

trains

electrophysiology

current-clamp

Modelování Huntingtonovy choroby a bněčná terapie při poškození míchy. / Huntington's disease modeling and stem cell therapy in spinal cord disorders and injury

Hruška-Plocháň, Marián

January 2013

Neurological disorders affect more than 14% of the population worldwide and together with traumatic brain and spinal cord injuries represent major health, public and economic burden of the society. Incidence of inherited and idiopathic neurodegenerative disorders and acute CNS injuries is growing globally while neuroscience society is being challenged by numerous unanswered questions. Therefore, research of the CNS disorders is essential. Since animal models of the CNS diseases and injuries represent the key step in the conversion of the basic research to the clinics, we focused our work on generation of new animal models and on their use in pre-clinical research. We generated and characterized transgenic minipig model of Huntington's disease (HD) which represents the only successful establishment of a transgenic model of HD in minipig which should be valuable for testing of long term safety of HD therapeutics. Next, we crossed the well characterized R6/2 mouse HD model with the gad mouse model which lacks the expression of UCHL1 which led to results that support the theory of "protective" role of mutant huntingtin aggregates and suggest that UCHL1 function(s) may be affected in HD disturbing certain branches of Ubiquitin Proteasome System. Traumatic spinal cord injury and Amyotrophic Lateral...