Characterization of synaptic dysfunction in an in vitro corticostriatal model system of Huntington’s disease

Huntington’s disease (HD) is an autosomal-dominant inherited neurodegenerative disease resulting from expanded amino acid (CAG) repeat in the gene that encodes protein huntingtin (Htt). HD remains incurable for now. A lot of evidence implicates aberrant synaptic connection between cortical and striatal neurons, a key component of HD pathophysilogy, which also leads to cognitive decline and motor disorders. In the present work synaptic activity between cortical and striatal neurons was studied on the corticostriatal co-culture model system of HD. Culture was prepared from HD mouse model YAC128. It was shown that first impairment appears on day 14 in vitro. Interestingly, these alterations occur in cortical neurons. Their activity in YAC128 cultures was higher than in cultures of wild-type neurons. At the same time, there were no differences in morphology of spines in striatal neurons. However, using novel optogenetic approach, we demonstrated that synaptic connections are already dysfunctional in YAC128 cultures. On day 19 in vitro the activity of cortical neurons in YAC128 cultures was reduced, which led to alterations on the post-synaptic side. Dendric spines of medium spiny neurons transformed and disappeared, which is possibly the main reason of neurodegenerative mechanisms during the HD development.     

The early cellular pathology of Huntington’s disease

Huntington's disease (HD) is an inherited neurodegenerative disorder that affects about one in 10,000 individuals in North America. The genetic defect responsible for the disease is an expansion of a CAG repeat that encodes a polyglutamine tract in the expressed protein, huntingtin. The disease is characterized by involuntary movements, cognitive impairment, and emotional disturbance. Despite the widespread expression of huntingtin, the brains of HD patients show selective neuronal loss in the striatum and the deep layers of the cerebral cortex. Recent studies have shown that polyglutamine expansion causes huntingtin to aggregate, to accumulate in the nucleus, and to interact abnormally with other proteins. Several cellular and animal models for HD have revealed that intranuclear accumulation of mutant huntingtin and the formation of neuropil aggregates precede neurological symptoms and neurodegeneration. Intranuclear huntingtin may affect nuclear function and the expression of genes important for neuronal function, whereas neuropil aggregates may interfere with neuritic transport and function. These early pathological events, which occur in the absence of neurodegeneration, may contribute to the neurological symptoms of HD and ultimately lead to neuronal cell death.     

Huntington’s disease—the sting in the tail

Huntington's disease (HD) is a progressive neurodegenerative condition caused by the abnormal expansion of a polyglutamine tract in the N‐terminus of the huntingtin protein. Over the last 20 years, HD pathogenesis has been explained by the generation of N‐terminal fragments containing the polyglutamine stretch. A new study from Frederic Saudou's group now investigates the function of the C‐terminal fragments generated upon cleavage and shows that these products may also contribute to cellular toxicity in HD (El‐Daher et al, 2015 ).     

Huntington’s disease: the coming of age

Huntington’s disease (HD) is caused due to an abnormal expansion of polyglutamine repeats in the first exon of huntingtin gene. The mutation in huntingtin causes abnormalities in the functioning of protein, leading to deleterious effects ultimately to the demise of specific neuronal cells. The disease is inherited in an autosomal dominant manner and leads to a plethora of neuropsychiatric behaviour and neuronal cell death mainly in striatal and cortical regions of the brain, eventually leading to death of the individual. The discovery of the mutant gene led to a surge in molecular diagnostics of the disease and in making different transgenic models in different organisms to understand the function of wild-type and mutant proteins. Despite difficult challenges, there has been a significant increase in understanding the functioning of the protein in normal and other gain-of-function interactions in mutant form. However, there have been no significant improvements in treatments of the patients suffering from this ailment and most of the treatment is still symptomatic. HD warrants more attention towards better understanding and treatment as more advancement in molecular diagnostics and therapeutic interventions are available. Several different transgenic models are available in different organisms, ranging from fruit flies to primate monkeys, for studies on understanding the pathogenicity of the mutant gene. It is the right time to assess the advancement in the field and try new strategies for neuroprotection using key pathways as target. The present review highlights the key ingredients of pathology in the HD and discusses important studies for drug trials and future goals for therapeutic interventions.     

Genetic analysis of candidate genes modifying the age-at-onset in Huntington’s disease

The expansion of a polymorphic CAG repeat in the HD gene encoding huntingtin has been identified as the major cause of Huntington’s disease (HD) and determines 42–73% of the variance in the age-at-onset of the disease. Polymorphisms in huntingtin interacting or associated genes are thought to modify the course of the disease. To identify genetic modifiers influencing the age at disease onset, we searched for polymorphic markers in the GRIK2, TBP, BDNF, HIP1 and ZDHHC17 genes and analysed seven of them by association studies in 980 independent European HD patients. Screening for unknown sequence variations we found besides several silent variations three polymorphisms in the ZDHHC17 gene. These and polymorphisms in the GRIK2, TBP and BDNF genes were analysed with respect to their association with the HD age-at-onset. Although some of the factors have been defined as genetic modifier factors in previous studies, none of the genes encoding GRIK2, TBP, BDNF and ZDHHC17 could be identified as a genetic modifier for HD.Electronic Supplementary Material Supplementary material is available to authorised users in the online version of this article at .     

Experience of experimental modelling of Huntington’s disease

Huntington’s disease (HD) is an autosomal dominant neurodegenerative disorder characterized by choreic involuntary movements, decline in cognitive functions, behavioral disturbances, and progressive neuronal death affecting primarily the striatum. The fatal nature of HD makes it important to search for new effective methods of its treatment, which requires the development of experimental models of the disease. These models can be created using 3-nitropropionic acid (3-NPA), which is a neurotoxin causing typical changes in motor skills and memory impairment in animals due to induction of oxidative stress, impaired glutathione defense, and destruction of striatal cells. We modeled HD in rats by chronic daily intraperitoneal administration of 3-NPA for 17 days. Systemic administration of a low dose of 3-NPA (10 mg/kg) induced hyperactivity of animals in the open field test (including movement redundancy as a hyperkinesia analogue) and had no effect on the behavior of the animals in the X-maze test. On the contrary, rats administered with a toxic dose of 3-NPA (20 mg/kg) exhibited a significant decrease in their motor activity and a cognitive decline in behavioral tests. A histopathological analysis revealed damage and loss of neurons and a decrease in expression of dopaminergic markers (tyrosine hydroxylase and plasma membrane dopamine transporter) in the striatum. The gliotoxic effect of 3-NPA was also found in the striatum, which was confirmed by immunohistochemical staining for astrocytic proteins: GFAP, glutamine synthetase, and aquaporin-4. This HD model may be helpful for testing new experimental therapies at different stages of HD-like neurodegeneration, including therapies based on cell neurotransplantation.     

Trace elements profile in the blood of Huntington’ disease patients

Huntington’ disease (HD) is an autosomal dominant neurodegenerative disease characterized by progressive motor, psychiatric, and cognitive deterioration. HD is, together with spinocerebellar ataxias, spinobulbar muscular atrophy and dentatorubral-pallido- luysian atrophy, one of the nine disorders caused by an expansion of glutamine residues in the causative protein where the polyglutamine expansion cause aberrant protein folding. Since an excessive metal’s accumulation in organs may induce protein misfolding and oxidative stress, we have studied the blood concentration of essential (Cr, Co, Cu, Fe, Mn, Mo, Ni, Se, Zn) and nonessential (As, Cd, Sb, Sn, V) trace elements in HD patients.We found increased levels of the essential elements iron, chromium, selenium and zinc and of the nonessential element arsenic in the blood of HD patients.Since alteration in metals homeostasis may contribute to the pathogenesis of neurodegenerative disease and could eventually constitute a target for therapy, we may suggest the utilize of the blood metal profile as a further in vivo tool to study and characterize Huntington disease.     

Metabonomic Characterization of the 3-Nitropropionic Acid Rat Model of Huntington’s Disease

3-Nitropropionic acid (3-NP)-induced neurotoxicity can be used as a model for the genetic neurodegenerative disorder Huntington’s disease (HD). A metabolic profiling strategy was adopted to explore the biochemical consequences of 3-NP administered to rats in specific brain regions. ¹H NMR spectroscopy was used to characterize the metabolite composition of several brain regions following 3-NP-intoxication. Dose-dependent increases in succinate levels were observed in all neuroanatomical regions, resulting from the 3-NP-induced inhibition of succinate dehydrogenase. Global decreases in taurine and GABA were observed in the majority of brain regions, whereas altered lipid profiles were observed only in the globus pallidus and dorsal striatum. Depleted phosphatidylcholine and elevated glycerol levels, which are indicative of apoptosis, were also observed in the frontal cortex of the 3-NP model. Many of the metabolic anomalies are consistent with those reported in HD. The 3-NP-induced model of HD provides a means of monitoring potential mechanisms of pathology and therapeutic response for drug interventions, which can be efficiently assessed using metabolic profiling strategies.     

Mitochondrial functional alterations in relation to pathophysiology of Huntington’s disease

Huntington’s disease (HD) is an autosomal dominant neurodegenerative disease which is characterized by psychiatric symptoms, involuntary choreiform movements and dementia with maximum degeneration occurring in striatum and cerebral cortex. Several studies implicate mitochondrial dysfunction to the selective neurodegeneration happening in this disorder. Calcium buffering imbalance and oxidative stress in the mitochondria, critically impaired movement across axons and abnormal fission or fusion of this organelle in the cells are some of the salient features that results in the loss of mitochondrial electron transport chain (ETC) complex function in HD. Although several models involving mutant huntingtin, excitotoxins and mitochondrial complex-II inhibitors have been used to explore the disease, it is not clear how disturbances in mitochondrial functioning is associated with such selective neurodegeneration, or in the expression of huntingtonian phenotypes in animals or man. We have carefully assessed various mitochondrial abnormalities observed in human patient samples, postmortem HD brains, cellular, vertebrate and invertebrate models of the disease, to conclude that ETC dysfunction is an integral part of the disease and justify a causal role of mitochondrial ETC dysfunction for the genesis of this disorder