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Investigating the molecular and cellular basis of pathogenesis in Huntington's diseaseKennedy, Laura January 2002 (has links)
No description available.
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The protein SS18L1 is a potent suppressor of polyQ-mediated huntingtin aggregation and toxicityMöller, Annekathrin 03 September 2012 (has links)
Huntington’s Disease (HD) ist eine neurodegenerative Erkrankung, die sich durch motorische, kognitive sowie psychiatrische Beeinträchtigungen auszeichnet. Die Verlängerung eines Polyglutamin (polyQ)-Abschnittes im Protein Huntingtin (Htt) über 37 Qs hinaus bedingt die Aggregation des mutierten Proteins (mHtt) und dessen Ablagerung in neuronalen Einschlüssen. Als potenzieller Modulator der polyQ-abhängigen mHtt Aggregation und Toxizität wurde der Q-reiche Transkriptionstransaktivator SS18L1 in silico identifiziert. Rekombinantes Volllängen-SS18L1 sowie die beiden verkürzten Fragmente SS18L1_NM und SS18L1_C weisen in wässriger Lösung einen hohen Anteil an Random-Coil-Strukturen auf und bilden Oligomere. Alle SS18L1-Proteine verzögern dosisabhängig die spontane Aggregation eines Htt Exon 1 Fragmentes mit 49 Glutaminen (Ex1Q49). Dabei wird die Entstehung SDS-stabiler Ex1Q49 Aggregate durch die Stabilisierung von Ex1Q49 Mono- und Oligomeren gebremst. In HEK293 Zellen verringern rekombinante SS18L1-Proteine sowohl die Anzahl der SDS-unlöslichen Ex1Q49-Aggregate als auch die mHtt-vermittelte Zytotoxizität. Auch hierbei scheint eine Stabilisierung früher Aggregatspezies, wahrscheinlich durch die Interaktion der SS18L1-Proteine mit dem jeweiligen mHtt Fragment, eine wesentliche Rolle zu spielen. Entsprechende Interaktionen konnten mittels LUMIER-Studien und konfokaler Mikroskopie nachgewiesen werden. Humanes, exogenes SS18L1 unterdrückt die polyQ-bedingte Aggregation in einem C. elegans-Modell für HD und in transgenen R6/2 HD-Mäusen sind die Mengen an endogenem SS18L1 im Vergleich zu Wildtyp-Mäusen verändert. Beides weist darauf hin, dass SS18L1 auch in vivo von Relevanz sein könnte. Dafür spricht zudem, dass murines SS18L1 in Gehirnen von R6/2-Mäusen mit neuronalen mHtt-Aggregaten co-lokalisiert. Die Ergebnisse dieser Arbeit könnten einen Ausgangspunkt für die Entwicklung neuer Therapieansätze und die weitere Erforschung der HD Pathologie darstellen. / Huntington’s Disease (HD) is a neurodegenerative disease, which is characterised by motor, cognitive and psychiatric disturbances. The abnormal extension of an N-terminal polyQ tract in the protein huntingtin (Htt) results in aggregation of the mutant protein (mHtt) and the deposition of neuronal inclusions. The Q-rich transcriptional transactivator SS18L1 was identified in silico as a potential modulator of polyQ-mediated mHtt aggregation and toxicity. Recombinant full-length SS18L1 and the truncated fragments SS18L1_NM and SS18L1_C have a high random-coil content and form oligomeric structures in aqueous solutions. In addition, all three proteins delay the spontaneous aggregation of an Htt exon 1 fragment with a stretch of 49 glutamines (Ex1Q49). The formation of SDS-resistant Ex1Q49 aggregates is postponed in a concentration-dependent manner as monomers and oligomers, appearing early in the amyloid formation cascade, are stabilised. In mammalian cells recombinant SS18L1 proteins reduce both the number of SDS-stable Ex1Q49 aggregates and mHtt-induced cytotoxicity. These effects are likely due to the stabilisation of early aggregation intermediates, which could result from interactions of the SS18L1 proteins with the respective mutant Htt exon 1 fragment. Such interactions have been demonstrated employing a LUMIER assay and confocal microscopy. Exogenous human SS18L1 suppresses polyQ-mediated aggregation in a C. elegans model of HD and levels of endogenous SS18L1 are altered in transgenic R6/2 HD mice compared to wild type mice. As a consequence, SS18L1 might be of relevance in vivo. This is also supported by the finding that murine SS18L1 interacts with mHtt inclusions in R6/2 mice. The results of this study could provide a basis for the development of a therapeutical strategy or for the further elucidation of HD pathology.
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Rôle de la huntingtine dans le muscle / Physiopathological role of huntingtine in musclePoreau, Brice 11 October 2017 (has links)
La maladie de Huntington (HD) est une pathologie génétique multisystémique neurodégénérative rare caractérisée par des atteintes motrices, cognitives et psychiatriques. Elle est due à une augmentation de la répétition de triplet CAG dans l'exon 1 du gène HTT, dont la taille normale est de 6 à 35 répétitions. Cette expansion de triplets conduit à la présence d'une répétition de glutamine de taille anormale dans l'extrémité N-terminale de la protéine huntingtine (HTT). Les conséquences de la mutation sont d’une part la diminution de l’expression de la protéine non mutée et d’autre part l’expression d’une protéine mutée. L’une des fonctions de la HTT est le transport intracellulaire de vésicules le long des microtubules dans les neurones. Par ailleurs, une phénocopie : Huntington disease like 2 maladie ayant un phénotype similaire, est due à une perte de fonction de la junctophilin-3 ayant pour rôle l’établissement de points de contact entre la membrane plasmique et le reticulum endoplasmique au niveau neuronal. Les présents travaux visent à découvrir les mécanismes au sein desquels la HTT est impliquée dans un modèle différent de la cellule neuronale : la cellule musculaire. En effet, les points de contact nommées triades sont le cœur du couplage excitation-contraction. Les travaux ont permis de montrer, après avoir créé des modèles cellulaires et in vivo avec baisse d’expression de la protéine, un défaut de la fonction musculaire au niveau cellulaire comme au niveau physiologique. Les relâchements calciques sont altérés. La force est diminuée. De plus, ces altérations de fonctionnement sont corrélées à une baisse d’expression des principaux récepteurs de la triade. Enfin, une fraction exogène de la partie N-terminale de la protéine non mutée restaure les défauts calciques observés. La huntingtine a donc un rôle prépondérant dans la fonction princeps du muscle : la contraction. / Huntington Disease (HD) is a rare multisystemic neurodegenerative genetic disorder, which combines psychiatric, cognitive and motor alterations. It is caused by an increase in CAG repeats in the huntingtin gene, resulting in an expansion of polyglutamine stretch in the protein. This induced a loss of the huntingtin protein (HTT) normal function associated with production of a mutant protein. HTT is an ubiquitous microtubules associated protein, with numerous functions among which vesicles and organelles traffic along microtubules. Along this line, one of its functions could be the traffic of reticulum vesicles to form contact point with the plasma membrane in neurons. Moreover, a phenocopy named Huntington’s disease like 2 is due to junctophilin-3 loss of function. Junctophilin 3 is involved in contact points between endoplasmic reticulum and plasma membrane in neurons. These studies are dedicated to the validation of the hypothesis of the role of HTT in contact points between endoplasmic reticulum and plasma membrane in another model, in which contacts between reticulum and plasma membrane are of major importance: the skeletal muscle cell. Indeed, the contact points between sarcoplasmic reticulum and plasma membrane (T-Tubule), called the triads, are the basis of excitation-contraction coupling in muscle. In these studies, we develop cellular and animals models with a loss of expression of HTT in skeletal muscle specifically. Theses studies show that calcium release is altered at the cellular level and muscle force is altered at animal model level. Theses alterations are correlated with loss of expression of the main receptors of the triad. Finally, fragment of the normal protein can restore calcium defects. Theses studies put forward the role of huntingtine in skeletal muscle.
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Identification of novel palmitoyl acyl transferases and characterization of the role of Huntingtin palmitoylation in Huntington DiseaseHuang, Kun 11 1900 (has links)
In neurons, modification by the lipid palmitate regulates trafficking and function of signaling molecules, neurotransmitter receptors and associated synaptic scaffolding proteins. HIP14 (huntingtin interacting protein 14) is the first identified and characterized mammalian palmitoyl transferase that regulates this process. I have shown that HIP14 has striking effects on modulating trafficking and function of many proteins important for synapse formation and plasticity such as PSD-95, a postsynaptic scaffolding molecule.
The importance of the finding that HIP14 is a neuronal palmitoyl transferase is further emphasized by our recent discovery that huntingtin protein folding, trafficking and function are regulated by the enzyme HIP14. Expansion of the polyglutamine tract in huntingtin as seen in Huntington Disease (HD) results in reduced association with HIP14 and decreased palmitoylation of huntingtin, which contributes to the formation of inclusion bodies and enhanced neuronal toxicity. By manipulating HIP14 levels through expression or knockdown, we can manipulate the number of huntingtin inclusion bodies and neuronal cell viability. Overall, these discoveries offer novel mechanism for HD pathogenesis and provide new approaches to therapy for HD.
The tight association of HIP14 with wild-type huntingtin, which differs from other known enzyme-substrate interactions, indicates that huntingtin serves other functions beyond being a substrate of HIP14. I have discovered that, in vitro, wild-type huntingtin may facilitate activity of HIP14 to palmitoylate other neuronal substrates such as SNAP25, PSD95 and GAD65. By contrast, mutant htt does not act this way, probably due to lack of interaction with HIP14. Furthermore, immunoprecipitated HIP14 from huntingtin+/- mice also exhibits less enzyme activity in palmitoylating GST-SNAP25 in vitro, suggesting that decreased huntingtin expression compromises HIP14 activity. In vivo, using Acyl Biotin Exchange assay, I have also found that palmitoylation of a number of presynaptic and postsynaptic proteins that are involved in neurotransmission are reduced in huntingtin+/- mice. This study not only ascribes an important biochemical function to wild-type huntingtin, but also suggests that defects in protein palmitoylation in general due to mutant huntingtin lack of ability to facilitate HIP14 activity may contribute to the pathogenesis of HD.
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Post-translational myristoylation during cell deathMartin, Dale David Orr Unknown Date
No description available.
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Identification of novel palmitoyl acyl transferases and characterization of the role of Huntingtin palmitoylation in Huntington DiseaseHuang, Kun 11 1900 (has links)
In neurons, modification by the lipid palmitate regulates trafficking and function of signaling molecules, neurotransmitter receptors and associated synaptic scaffolding proteins. HIP14 (huntingtin interacting protein 14) is the first identified and characterized mammalian palmitoyl transferase that regulates this process. I have shown that HIP14 has striking effects on modulating trafficking and function of many proteins important for synapse formation and plasticity such as PSD-95, a postsynaptic scaffolding molecule.
The importance of the finding that HIP14 is a neuronal palmitoyl transferase is further emphasized by our recent discovery that huntingtin protein folding, trafficking and function are regulated by the enzyme HIP14. Expansion of the polyglutamine tract in huntingtin as seen in Huntington Disease (HD) results in reduced association with HIP14 and decreased palmitoylation of huntingtin, which contributes to the formation of inclusion bodies and enhanced neuronal toxicity. By manipulating HIP14 levels through expression or knockdown, we can manipulate the number of huntingtin inclusion bodies and neuronal cell viability. Overall, these discoveries offer novel mechanism for HD pathogenesis and provide new approaches to therapy for HD.
The tight association of HIP14 with wild-type huntingtin, which differs from other known enzyme-substrate interactions, indicates that huntingtin serves other functions beyond being a substrate of HIP14. I have discovered that, in vitro, wild-type huntingtin may facilitate activity of HIP14 to palmitoylate other neuronal substrates such as SNAP25, PSD95 and GAD65. By contrast, mutant htt does not act this way, probably due to lack of interaction with HIP14. Furthermore, immunoprecipitated HIP14 from huntingtin+/- mice also exhibits less enzyme activity in palmitoylating GST-SNAP25 in vitro, suggesting that decreased huntingtin expression compromises HIP14 activity. In vivo, using Acyl Biotin Exchange assay, I have also found that palmitoylation of a number of presynaptic and postsynaptic proteins that are involved in neurotransmission are reduced in huntingtin+/- mice. This study not only ascribes an important biochemical function to wild-type huntingtin, but also suggests that defects in protein palmitoylation in general due to mutant huntingtin lack of ability to facilitate HIP14 activity may contribute to the pathogenesis of HD.
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Identification of novel palmitoyl acyl transferases and characterization of the role of Huntingtin palmitoylation in Huntington DiseaseHuang, Kun 11 1900 (has links)
In neurons, modification by the lipid palmitate regulates trafficking and function of signaling molecules, neurotransmitter receptors and associated synaptic scaffolding proteins. HIP14 (huntingtin interacting protein 14) is the first identified and characterized mammalian palmitoyl transferase that regulates this process. I have shown that HIP14 has striking effects on modulating trafficking and function of many proteins important for synapse formation and plasticity such as PSD-95, a postsynaptic scaffolding molecule.
The importance of the finding that HIP14 is a neuronal palmitoyl transferase is further emphasized by our recent discovery that huntingtin protein folding, trafficking and function are regulated by the enzyme HIP14. Expansion of the polyglutamine tract in huntingtin as seen in Huntington Disease (HD) results in reduced association with HIP14 and decreased palmitoylation of huntingtin, which contributes to the formation of inclusion bodies and enhanced neuronal toxicity. By manipulating HIP14 levels through expression or knockdown, we can manipulate the number of huntingtin inclusion bodies and neuronal cell viability. Overall, these discoveries offer novel mechanism for HD pathogenesis and provide new approaches to therapy for HD.
The tight association of HIP14 with wild-type huntingtin, which differs from other known enzyme-substrate interactions, indicates that huntingtin serves other functions beyond being a substrate of HIP14. I have discovered that, in vitro, wild-type huntingtin may facilitate activity of HIP14 to palmitoylate other neuronal substrates such as SNAP25, PSD95 and GAD65. By contrast, mutant htt does not act this way, probably due to lack of interaction with HIP14. Furthermore, immunoprecipitated HIP14 from huntingtin+/- mice also exhibits less enzyme activity in palmitoylating GST-SNAP25 in vitro, suggesting that decreased huntingtin expression compromises HIP14 activity. In vivo, using Acyl Biotin Exchange assay, I have also found that palmitoylation of a number of presynaptic and postsynaptic proteins that are involved in neurotransmission are reduced in huntingtin+/- mice. This study not only ascribes an important biochemical function to wild-type huntingtin, but also suggests that defects in protein palmitoylation in general due to mutant huntingtin lack of ability to facilitate HIP14 activity may contribute to the pathogenesis of HD. / Medicine, Faculty of / Graduate
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Oxidative metabolism and mitochondrial calcium handling in mouse models of Huntington's DiseaseHamilton, James M. 23 August 2017 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Huntington’s disease (HD) is an autosomal dominantly inherited, fatal
neurodegenerative disorder for which there is no cure. HD is clinically characterized by
progressively worsening motor, cognitive, and psychiatric disturbances. Currently
available therapeutics for HD only treat symptoms, but do not address underlying
disease pathology. HD pathogenesis is linked to a mutation in the huntingtin gene, which
encodes a protein called huntingtin (Htt) that is normally involved in a variety of cellular
processes. In healthy individuals, the N-terminus of huntingtin possesses a
polyglutamine stretch containing less than 35 glutamines, however, the mutated
huntingtin protein (mHtt) has an elongated polyglutamine tract that correlates with the
development of HD. The mechanism of deleterious action by mHtt is unknown, but a
major hypothesis postulates that mHtt may cause mitochondrial dysfunction. However,
the data regarding involvement of mitochondrial impairment in HD pathology are
contradictory. Some investigators previously reported, for example, that mHtt
suppresses mitochondrial respiratory activity and decreases mitochondrial Ca2+ uptake
capacity. However, other investigators found increased respiratory activity and
augmented mitochondrial Ca2+ uptake capacity.
We used transgenic mouse models of HD to investigate the effect of full-length
and fragments of mHtt on oxidative metabolism and Ca2+ handling using a combination
of isolated mitochondria, primary neurons, and whole-animal metabolic measurements.
We evaluated the effect of full-length mHtt on isolated mitochondria and primary neurons
from YAC128 mice. We found no alteration in respiratory activity or Ca2+ uptake
capacity, indicative of mitochondrial damage, between mitochondria or neurons from YAC128 mice compared to wild-type (WT) mice. Furthermore, we measured whole
animal oxidative metabolism and physical activity level and found that YAC128 mice do
not display any decline in metabolic and physical activity. Although full-length mHtt
expressing YAC128 mice may be a more faithful genetic recapitulation of HD, data
suggests mHtt fragments may be more toxic. To assess the effect of mHtt fragments, we
used isolated brain mitochondria and primary striatal neurons from the R6/2 mouse
model and found no significant impairment in respiration or Ca2+ handling. Thus, our
data strongly support the hypothesis that mHtt does not alter mitochondrial functions
assessed either with isolated mitochondria, primary neurons, or whole animals.
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Huntingtin N17 Domain is a Reactive Oxygen Species Sensor Regulating Huntingtin Phosphorylation and LocalizationDiGiovanni, Laura January 2016 (has links)
The huntingtin N17 domain is the master regulator of huntingtin intracellular localization. N17 is post-translationally modified, and phosphorylation of N17 serines 13 and 16 facilitate the stress dependent nuclear translocation of huntingtin by inhibiting CRM1 binding and nuclear export. In Huntington’s disease (HD), mutant huntingtin is hypo-phosphorylated and increasing N17 phosphorylation has been shown to be protective in HD mouse models. N17 phosphorylation is therefore a valid therapeutic sub-target of huntingtin. The ER stresses that have been previously characterized to affect huntingtin phosphorylation are broad, likely activating a plethora of response pathways. Thus, in this study, we sought to define a specific stress that could affect huntingtin phosphorylation and nuclear localization. Here we show that huntingtin localization and phosphorylation can be specifically affected by reactive oxygen species (ROS). We identify a highly conserved methionine at position 8 (M8) as the specific sensor of oxidative species within N17 and show the capacity of oxido-mimetic M8 point mutations to affect N17 structure, localization and phosphorylation. We also define a specific molecular mechanism whereby N17 oxidation promotes membrane dissociation, thus increasing kinase accessibility and subsequent phosphorylation. These results define a precise molecular mechanism for the normal biological regulation of huntingtin phosphorylation by oxidative signalling. This ability of huntingtin to sense ROS levels at the ER provides a link between age-associated stress and altered huntingtin function. It suggests that ROS stress due to aging may be a critical molecular trigger of HD that could explain the age-onset nature of disease. / Thesis / Master of Science (MSc)
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Excitotoxicity and bioenergetics in Huntington's disease transgenic neuronsCarrier, Raeann Lynn 04 September 2008 (has links)
No description available.
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