Striatal disorders dissociate mechanisms of enhanced and impaired response selection — Evidence from cognitive neurophysiology and computational modelling

Beste, Christian, Humphries, Mark, Saft, Carsten

15 July 2014

Paradoxically enhanced cognitive processes in neurological disorders provide vital clues to understanding neural function. However, what determines whether the neurological damage is impairing or enhancing is unclear. Here we use the performance of patients with two disorders of the striatum to dissociate mechanisms underlying cognitive enhancement and impairment resulting from damage to the same system. In a two-choice decision task, Huntington\'s disease patients were faster and less error prone than controls, yet a patient with the rare condition of benign hereditary chorea (BHC) was both slower and more error prone. EEG recordings confirmed significant differences in neural processing between the groups. Analysis of a computational model revealed that the common loss of connectivity between striatal neurons in BHC and Huntington\'s disease impairs response selection, but the increased sensitivity of NMDA receptors in Huntington\'s disease potentially enhances response selection. Crucially the model shows that there is a critical threshold for increased sensitivity: below that threshold, impaired response selection results. Our data and model thus predict that specific striatal malfunctions can contribute to either impaired or enhanced selection, and provide clues to solving the paradox of how Huntington\'s disease can lead to both impaired and enhanced cognitive processes.

Computersimulation

Basalganglien

Exekutive Funktionen

Benigne hereditäre Chorea

Chorea Huntington

EEG

TU Dresden

Publikationsfonds

Computational modelling

Basal ganglia

Executive control

Benign hereditary chorea

Huntington's disease

EEG

Technical University Dresden

Publication funds

ddc:610

rvk:XA 10000

AAV-vector mediated gene delivery for Huntington's Disease: an investigative therapeutic study

Kells, Adrian P

January 2007

Progressive degeneration in the central nervous system (CNS) of Huntington’s disease (HD) patients is a relentless debilitating process, resulting from the inheritance of a single gene mutation. With limited knowledge of the underlying pathological molecular mechanisms, pharmaceutical intervention has to-date not provided any effective clinical treatment strategies to attenuate or compensate the neuronal cell death. Attention has therefore turned to biotherapeutic molecules and novel treatment approaches to promote restoration and protection of selectively vulnerable populations of neurons in the HD brain. Rapid advances in vectorology and gene-based medicine over the past decade have opened the way for safe and efficient delivery of biotherapeutics to the CNS. With numerous factors known to regulate the development, plasticity and maintenance of the mammalian nervous system many proteins have emerged as potential therapeutic agents to alleviate HD progression. This investigative study utilised gene delivery vectors derived from the non-pathogenic adeno-associated virus (AAV) to direct high-level expression of brain-derived neurotrophic factor (BDNF), glial cell-line derived neurotrophic factor (GDNF), Bcl-xL or X-linked inhibitor of apoptosis protein (XIAP) within the rodent striatum. Maintenance of the basal ganglia and functional behaviour deficits were assessed following excitotoxic insult of the striatum by quinolinic acid (QA), a neurotoxic model of HD pathology. Enhanced striatal expression of BDNF prior to QA-induced lesioning provided maintenance of the striosome-matrix organisation of the striatum, attenuating impairments of sensorimotor behaviour with a 36-38% increase in the maintenance of DARPP-32 / krox-24 expressing striatal neurons, reduced striatal atrophy and increased maintenance of striatonigral projections. Higher levels of BDNF however induced seizures and weight-loss highlighting the need to provide regulatable control over biotherapeutic protein expression. Continuous high-expression of BDNF or GDNF resulted in a downregulation of intracellular signal mediating proteins including DARPP-32, with AAV-GDNF not found to enhance the overall maintenance of striatal neurons. Neither of the anti-apoptotic factors provided significant protection of transduced striatal neurons but tended towards ameliorating QA-induced behavioural deficits, displaying behaviour – pathology correlations with the survival of parvalbumin-expressing neurons in the globus pallidus. The results of this thesis suggest BDNF as a promising putative biotherapeutic for HD, but emphasises the requirement to control expression following gene delivery, and for further elucidation of the physiological impact that enhanced expression of endogenous factors has on the host cells. Additionally the maintenance of neural networks beyond the caudate-putamen will be vital to ensuring efficient clinical outcomes for HD. / Auckland Medical Research Foundation. Foundation for Research, Science and Technology. The University of Auckland.

Huntington's Disease

Gene Delivery

Adeno-associated virus

Brain derived neurotrophic factor

AAV-vector mediated gene delivery for Huntington's Disease: an investigative therapeutic study

Kells, Adrian P

January 2007

Progressive degeneration in the central nervous system (CNS) of Huntington’s disease (HD) patients is a relentless debilitating process, resulting from the inheritance of a single gene mutation. With limited knowledge of the underlying pathological molecular mechanisms, pharmaceutical intervention has to-date not provided any effective clinical treatment strategies to attenuate or compensate the neuronal cell death. Attention has therefore turned to biotherapeutic molecules and novel treatment approaches to promote restoration and protection of selectively vulnerable populations of neurons in the HD brain. Rapid advances in vectorology and gene-based medicine over the past decade have opened the way for safe and efficient delivery of biotherapeutics to the CNS. With numerous factors known to regulate the development, plasticity and maintenance of the mammalian nervous system many proteins have emerged as potential therapeutic agents to alleviate HD progression. This investigative study utilised gene delivery vectors derived from the non-pathogenic adeno-associated virus (AAV) to direct high-level expression of brain-derived neurotrophic factor (BDNF), glial cell-line derived neurotrophic factor (GDNF), Bcl-xL or X-linked inhibitor of apoptosis protein (XIAP) within the rodent striatum. Maintenance of the basal ganglia and functional behaviour deficits were assessed following excitotoxic insult of the striatum by quinolinic acid (QA), a neurotoxic model of HD pathology. Enhanced striatal expression of BDNF prior to QA-induced lesioning provided maintenance of the striosome-matrix organisation of the striatum, attenuating impairments of sensorimotor behaviour with a 36-38% increase in the maintenance of DARPP-32 / krox-24 expressing striatal neurons, reduced striatal atrophy and increased maintenance of striatonigral projections. Higher levels of BDNF however induced seizures and weight-loss highlighting the need to provide regulatable control over biotherapeutic protein expression. Continuous high-expression of BDNF or GDNF resulted in a downregulation of intracellular signal mediating proteins including DARPP-32, with AAV-GDNF not found to enhance the overall maintenance of striatal neurons. Neither of the anti-apoptotic factors provided significant protection of transduced striatal neurons but tended towards ameliorating QA-induced behavioural deficits, displaying behaviour – pathology correlations with the survival of parvalbumin-expressing neurons in the globus pallidus. The results of this thesis suggest BDNF as a promising putative biotherapeutic for HD, but emphasises the requirement to control expression following gene delivery, and for further elucidation of the physiological impact that enhanced expression of endogenous factors has on the host cells. Additionally the maintenance of neural networks beyond the caudate-putamen will be vital to ensuring efficient clinical outcomes for HD. / Auckland Medical Research Foundation. Foundation for Research, Science and Technology. The University of Auckland.

Huntington's Disease

Gene Delivery

Adeno-associated virus

Brain derived neurotrophic factor

AAV-vector mediated gene delivery for Huntington's Disease: an investigative therapeutic study

Kells, Adrian P

January 2007

Progressive degeneration in the central nervous system (CNS) of Huntington’s disease (HD) patients is a relentless debilitating process, resulting from the inheritance of a single gene mutation. With limited knowledge of the underlying pathological molecular mechanisms, pharmaceutical intervention has to-date not provided any effective clinical treatment strategies to attenuate or compensate the neuronal cell death. Attention has therefore turned to biotherapeutic molecules and novel treatment approaches to promote restoration and protection of selectively vulnerable populations of neurons in the HD brain. Rapid advances in vectorology and gene-based medicine over the past decade have opened the way for safe and efficient delivery of biotherapeutics to the CNS. With numerous factors known to regulate the development, plasticity and maintenance of the mammalian nervous system many proteins have emerged as potential therapeutic agents to alleviate HD progression. This investigative study utilised gene delivery vectors derived from the non-pathogenic adeno-associated virus (AAV) to direct high-level expression of brain-derived neurotrophic factor (BDNF), glial cell-line derived neurotrophic factor (GDNF), Bcl-xL or X-linked inhibitor of apoptosis protein (XIAP) within the rodent striatum. Maintenance of the basal ganglia and functional behaviour deficits were assessed following excitotoxic insult of the striatum by quinolinic acid (QA), a neurotoxic model of HD pathology. Enhanced striatal expression of BDNF prior to QA-induced lesioning provided maintenance of the striosome-matrix organisation of the striatum, attenuating impairments of sensorimotor behaviour with a 36-38% increase in the maintenance of DARPP-32 / krox-24 expressing striatal neurons, reduced striatal atrophy and increased maintenance of striatonigral projections. Higher levels of BDNF however induced seizures and weight-loss highlighting the need to provide regulatable control over biotherapeutic protein expression. Continuous high-expression of BDNF or GDNF resulted in a downregulation of intracellular signal mediating proteins including DARPP-32, with AAV-GDNF not found to enhance the overall maintenance of striatal neurons. Neither of the anti-apoptotic factors provided significant protection of transduced striatal neurons but tended towards ameliorating QA-induced behavioural deficits, displaying behaviour – pathology correlations with the survival of parvalbumin-expressing neurons in the globus pallidus. The results of this thesis suggest BDNF as a promising putative biotherapeutic for HD, but emphasises the requirement to control expression following gene delivery, and for further elucidation of the physiological impact that enhanced expression of endogenous factors has on the host cells. Additionally the maintenance of neural networks beyond the caudate-putamen will be vital to ensuring efficient clinical outcomes for HD. / Auckland Medical Research Foundation. Foundation for Research, Science and Technology. The University of Auckland.

Huntington's Disease

Gene Delivery

Adeno-associated virus

Brain derived neurotrophic factor

AAV-vector mediated gene delivery for Huntington's Disease: an investigative therapeutic study

Kells, Adrian P

January 2007

Progressive degeneration in the central nervous system (CNS) of Huntington’s disease (HD) patients is a relentless debilitating process, resulting from the inheritance of a single gene mutation. With limited knowledge of the underlying pathological molecular mechanisms, pharmaceutical intervention has to-date not provided any effective clinical treatment strategies to attenuate or compensate the neuronal cell death. Attention has therefore turned to biotherapeutic molecules and novel treatment approaches to promote restoration and protection of selectively vulnerable populations of neurons in the HD brain. Rapid advances in vectorology and gene-based medicine over the past decade have opened the way for safe and efficient delivery of biotherapeutics to the CNS. With numerous factors known to regulate the development, plasticity and maintenance of the mammalian nervous system many proteins have emerged as potential therapeutic agents to alleviate HD progression. This investigative study utilised gene delivery vectors derived from the non-pathogenic adeno-associated virus (AAV) to direct high-level expression of brain-derived neurotrophic factor (BDNF), glial cell-line derived neurotrophic factor (GDNF), Bcl-xL or X-linked inhibitor of apoptosis protein (XIAP) within the rodent striatum. Maintenance of the basal ganglia and functional behaviour deficits were assessed following excitotoxic insult of the striatum by quinolinic acid (QA), a neurotoxic model of HD pathology. Enhanced striatal expression of BDNF prior to QA-induced lesioning provided maintenance of the striosome-matrix organisation of the striatum, attenuating impairments of sensorimotor behaviour with a 36-38% increase in the maintenance of DARPP-32 / krox-24 expressing striatal neurons, reduced striatal atrophy and increased maintenance of striatonigral projections. Higher levels of BDNF however induced seizures and weight-loss highlighting the need to provide regulatable control over biotherapeutic protein expression. Continuous high-expression of BDNF or GDNF resulted in a downregulation of intracellular signal mediating proteins including DARPP-32, with AAV-GDNF not found to enhance the overall maintenance of striatal neurons. Neither of the anti-apoptotic factors provided significant protection of transduced striatal neurons but tended towards ameliorating QA-induced behavioural deficits, displaying behaviour – pathology correlations with the survival of parvalbumin-expressing neurons in the globus pallidus. The results of this thesis suggest BDNF as a promising putative biotherapeutic for HD, but emphasises the requirement to control expression following gene delivery, and for further elucidation of the physiological impact that enhanced expression of endogenous factors has on the host cells. Additionally the maintenance of neural networks beyond the caudate-putamen will be vital to ensuring efficient clinical outcomes for HD. / Auckland Medical Research Foundation. Foundation for Research, Science and Technology. The University of Auckland.

Huntington's Disease

Gene Delivery

Adeno-associated virus

Brain derived neurotrophic factor

AAV-vector mediated gene delivery for Huntington's Disease: an investigative therapeutic study

Kells, Adrian P

January 2007

Progressive degeneration in the central nervous system (CNS) of Huntington’s disease (HD) patients is a relentless debilitating process, resulting from the inheritance of a single gene mutation. With limited knowledge of the underlying pathological molecular mechanisms, pharmaceutical intervention has to-date not provided any effective clinical treatment strategies to attenuate or compensate the neuronal cell death. Attention has therefore turned to biotherapeutic molecules and novel treatment approaches to promote restoration and protection of selectively vulnerable populations of neurons in the HD brain. Rapid advances in vectorology and gene-based medicine over the past decade have opened the way for safe and efficient delivery of biotherapeutics to the CNS. With numerous factors known to regulate the development, plasticity and maintenance of the mammalian nervous system many proteins have emerged as potential therapeutic agents to alleviate HD progression. This investigative study utilised gene delivery vectors derived from the non-pathogenic adeno-associated virus (AAV) to direct high-level expression of brain-derived neurotrophic factor (BDNF), glial cell-line derived neurotrophic factor (GDNF), Bcl-xL or X-linked inhibitor of apoptosis protein (XIAP) within the rodent striatum. Maintenance of the basal ganglia and functional behaviour deficits were assessed following excitotoxic insult of the striatum by quinolinic acid (QA), a neurotoxic model of HD pathology. Enhanced striatal expression of BDNF prior to QA-induced lesioning provided maintenance of the striosome-matrix organisation of the striatum, attenuating impairments of sensorimotor behaviour with a 36-38% increase in the maintenance of DARPP-32 / krox-24 expressing striatal neurons, reduced striatal atrophy and increased maintenance of striatonigral projections. Higher levels of BDNF however induced seizures and weight-loss highlighting the need to provide regulatable control over biotherapeutic protein expression. Continuous high-expression of BDNF or GDNF resulted in a downregulation of intracellular signal mediating proteins including DARPP-32, with AAV-GDNF not found to enhance the overall maintenance of striatal neurons. Neither of the anti-apoptotic factors provided significant protection of transduced striatal neurons but tended towards ameliorating QA-induced behavioural deficits, displaying behaviour – pathology correlations with the survival of parvalbumin-expressing neurons in the globus pallidus. The results of this thesis suggest BDNF as a promising putative biotherapeutic for HD, but emphasises the requirement to control expression following gene delivery, and for further elucidation of the physiological impact that enhanced expression of endogenous factors has on the host cells. Additionally the maintenance of neural networks beyond the caudate-putamen will be vital to ensuring efficient clinical outcomes for HD. / Auckland Medical Research Foundation. Foundation for Research, Science and Technology. The University of Auckland.

Huntington's Disease

Gene Delivery

Adeno-associated virus

Brain derived neurotrophic factor

Development of new high-throughput technology and combinatorial therapeutic strategy applicable to Huntington's disease and other amyloidoses / Développement de nouvelles technologie à haut débit et stratégie thérapeutique combinatoire applicables à la maladie de Huntington et d'autres amyloïdoses

Aviolat, Hubert

16 September 2015

Moduler l’agrégation de protéines amyloïdes est thérapeutiquement pertinent (p. ex. la polyneuropathie amyloïde familiale traitée avec le Tafamidis). Cependant, pour de nombreuses amyloïdoses, il n’existe pas encore de modulateur d'agrégation efficace pour thérapie. Il a été récemment montré que combiner des composés qui modulent l’agrégation d’amyloïdes peut résulter en des effets synergiques. Une stratégie de criblage combinatoire, pour identifier des cocktails synergiques de composés, pourrait donc conduire à une percée thérapeutique pour de nombreuses amyloïdoses. Cependant, les technologies à haut débit existantes ne sont pas adaptées pour le criblage combinatoire.J’ai développé SynAggreg – une technologie in vitro à haut débit très sensible, précise, reproductible, peu coûteuse et flexible - qui permet d'identifier à la fois des inhibiteurs et des accélérateurs d'agrégation, de caractériser leur mécanisme d'action sur la cinétique d'agrégation et de les classer par leur efficacité. SynAggreg est également la première technologie adaptée au criblage combinatoire et pour l’étude d’effets synergiques de manière fiable. Enfin, cette nouvelle technologie peut être facilement adaptée à plusieurs amyloïdoses en remplaçant la partie amyloïde de la protéine de fusion par des techniques de biologie moléculaire. Ainsi, SynAggreg apparaît comme une boîte à outils pour la recherche fondamentale et appliquée et possède un fort potentiel de valorisation. / Modulating amyloid proteins aggregation is therapeutically relevant (e.g. the familial amyloid polyneuropathy treated with Tafamidis). However, for many amyloidoses, there is yet no efficient aggregation modulator for therapy. It was recently shown that combining compounds that modulate the aggregation of amyloids can result in synergistic effects. A combinatorial screening strategy to identify synergistic cocktails of compounds could thus lead to a therapeutic break through for many amyloidoses. However, existing high-throughput technologies are not adapted for combinatorial screening.I developed SynAggreg - a very sensitive, accurate, reproducible, cost effective, flexible and high-throughput in vitro technology - which allows identifying both aggregation inhibitors and accelerators, characterizing their mechanism of action on aggregation kinetics and ranking them by their efficiency. SynAggreg is also the first technology suitable for combinatorial screening and for studying reliably synergistic effects of combinations of compounds. Finally, this new technology can be easily adapted to several amyloidoses by replacing the amyloid part of the fusion protein with molecular biology techniques. Thus, SynAggreg appears as a toolbox for fundamental and applied research, and has a high potential for valorization.

Maladie de Huntington

Polyglutamine

Protéines amyloïdes

Protéines désordonnées intrinsèques

Criblage à haut-débit

Modulateur d'agrégation

Stratégie thérapeutique combinatoire

SynAggreg

Huntington's disease

Polyglutamine diseases

Amyloid

Intrinsically disoredered protein

High-throughput screening

Aggregation modulators

Combinatorial therapeutic strategy

SynAggreg

615.7

616.83

572.8

Striatal disorders dissociate mechanisms of enhanced and impaired response selection — Evidence from cognitive neurophysiology and computational modelling

Beste, Christian, Humphries, Mark, Saft, Carsten

15 July 2014

Paradoxically enhanced cognitive processes in neurological disorders provide vital clues to understanding neural function. However, what determines whether the neurological damage is impairing or enhancing is unclear. Here we use the performance of patients with two disorders of the striatum to dissociate mechanisms underlying cognitive enhancement and impairment resulting from damage to the same system. In a two-choice decision task, Huntington\'s disease patients were faster and less error prone than controls, yet a patient with the rare condition of benign hereditary chorea (BHC) was both slower and more error prone. EEG recordings confirmed significant differences in neural processing between the groups. Analysis of a computational model revealed that the common loss of connectivity between striatal neurons in BHC and Huntington\'s disease impairs response selection, but the increased sensitivity of NMDA receptors in Huntington\'s disease potentially enhances response selection. Crucially the model shows that there is a critical threshold for increased sensitivity: below that threshold, impaired response selection results. Our data and model thus predict that specific striatal malfunctions can contribute to either impaired or enhanced selection, and provide clues to solving the paradox of how Huntington\'s disease can lead to both impaired and enhanced cognitive processes.

info:eu-repo/classification/ddc/610

ddc:610

A CNS-Active siRNA Chemical Scaffold for the Treatment of Neurodegenerative Diseases

Alterman, Julia F.

13 May 2019

Small interfering RNAs (siRNAs) are a promising class of drugs for treating genetically-defined diseases. Therapeutic siRNAs enable specific modulation of gene expression, but require chemical architecture that facilitates efficient in vivodelivery. siRNAs are informational drugs, therefore specificity for a target gene is defined by nucleotide sequence. Thus, developing a chemical scaffold that efficiently delivers siRNA to a particular tissue provides an opportunity to target any disease-associated gene in that tissue. The goal of this project was to develop a chemical scaffold that supports efficient siRNA delivery to the brain for the treatment of neurodegenerative diseases, specifically Huntington’s disease (HD). HD is an autosomal dominant neurodegenerative disorder that affects 3 out of every 100,000 people worldwide. This disorder is caused by an expansion of CAG repeats in the huntingtin gene that results in significant atrophy in the striatum and cortex of the brain. Silencing of the huntingtin gene is considered a viable treatment option for HD. This project: 1) identified a hyper-functional sequence for siRNA targeting the huntingtin gene, 2) developed a fully chemically modified architecture for the siRNA sequence, and 3) identified a new structure for siRNA central nervous system (CNS) delivery—Divalent-siRNA (Di-siRNA). Di-siRNAs, which are composed of two fully chemically-stabilized, phosphorothioate-containing siRNAs connected by a linker, support potent and sustained gene modulation in the CNS of mice and non-human primates. In mice, Di-siRNAs induced potent silencing of huntingtin mRNA and protein throughout the brain one month after a single intracerebroventricular injection. Silencing persisted for at least six months, with the degree of gene silencing correlating to guide strand tissue accumulation levels. In Cynomolgus macaques, a bolus injection exhibited significant distribution and robust silencing throughout the brain and spinal cord without detectable toxicity. This new siRNA scaffold opens the CNS for RNAi-based gene modulation, creating a path towards developing treatments for genetically-defined neurological disorders.

RNAi

siRNA

Huntington's disease

neurodegenerative disease

brain

delivery

Biotechnology

Chemical and Pharmacologic Phenomena

Medical Biotechnology

Medical Neurobiology

Medicinal Chemistry and Pharmaceutics

Neurosciences

Other Neuroscience and Neurobiology

Pharmaceutics and Drug Design

Translational Medical Research

Senzorické a senzitivní dysfunkce u neurodegenerativních postižení bazálních ganglií. / Sensory and sensitive dysfunctions in neurodegenerative disorders of the basal ganglia.

Kopal, Aleš

January 2019

Complex functions of the basal ganglia are affected by numerous sensory and sensitive stimuli. In our studies, we investigated parameters of sense of smell and vision in neurodegenerative diseases of the basal ganglia - Parkinson's disease (PD) and Huntington's disease (HD). In the first study, we use Odourized Markers Test (OMT) to determine its applicability in PD patients, and to determine whether it distinguishes olfactory disorders between neurodegenerative and other disorders. Results show that OMT is applicable for PD patients and comparable to Sniffin' Sticks as it demonstrates gains of lower scores in PD patients compared to healthy subjects, but they do not differentiate other etiology of olfactory disorders. In the next study, we tested the pleasantness of odor stimulants in PD patients using New test of odor pleasantness (NTOP). We investigated suitability and validity of its use. We found that PD patients had lower odor rating score compared to healthy group correlated with Sniffin' Sticks and OMT. In the following study, we examined whether PD patients with visual hallucinations (PDH+) have structural retinal changes measured by optical coherence tomography (OCT) and functional retinal changes examined by 2,5% contrast sensitivity test compared to PD patients without hallucinations...