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      Dystonia: Sparse Synapses for D2 Receptors in Striatum of a DYT1 Knock-out Mouse Model

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          Abstract

          Dystonia pathophysiology has been partly linked to downregulation and dysfunction of dopamine D2 receptors in striatum. We aimed to investigate the possible morpho-structural correlates of D2 receptor downregulation in the striatum of a DYT1 Tor1a mouse model. Adult control Tor1a+/+ and mutant Tor1a+/− mice were used. The brains were perfused and free-floating sections of basal ganglia were incubated with polyclonal anti-D2 antibody, followed by secondary immune-fluorescent antibody. Confocal microscopy was used to detect immune-fluorescent signals. The same primary antibody was used to evaluate D2 receptor expression by western blot. The D2 receptor immune-fluorescence appeared circumscribed in small disks (~0.3–0.5 µm diameter), likely representing D2 synapse aggregates, densely distributed in the striatum of Tor1a+/+ mice. In the Tor1a+/− mice the D2 aggregates were significantly smaller (µm 2 2.4 ± SE 0.16, compared to µm 2 6.73 ± SE 3.41 in Tor1a+/+) and sparse, with ~30% less number per microscopic field, value correspondent to the amount of reduced D2 expression in western blotting analysis. In DYT1 mutant mice the sparse and small D2 synapses in the striatum may be insufficient to “gate” the amount of presynaptic dopamine release diffusing in peri-synaptic space, and this consequently may result in a timing and spatially larger nonselective sphere of influence of dopamine action.

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          The early-onset torsion dystonia gene (DYT1) encodes an ATP-binding protein.

          Early-onset torsion dystonia is a movement disorder, characterized by twisting muscle contractures, that begins in childhood. Symptoms are believed to result from altered neuronal communication in the basal ganglia. This study identifies the DYT1 gene on human chromosome 9q34 as being responsible for this dominant disease. Almost all cases of early-onset dystonia have a unique 3-bp deletion that appears to have arisen idependently in different ethnic populations. This deletion results in loss of one of a pair of glutamic-acid residues in a conserved region of a novel ATP-binding protein, termed torsinA. This protein has homologues in nematode, rat, mouse and humans, with some resemblance to the family of heat-shock proteins and Clp proteases.
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            Loss of the dystonia-associated protein torsinA selectively disrupts the neuronal nuclear envelope.

            An enigmatic feature of many genetic diseases is that mutations in widely expressed genes cause tissue-specific illness. One example is DYT1 dystonia, a neurodevelopmental disease caused by an in-frame deletion (Deltagag) in the gene encoding torsinA. Here we show that neurons from both torsinA null (Tor1a(-/-)) and homozygous disease mutant "knockin" mice (Tor1a(Deltagag/Deltagag)) contain severely abnormal nuclear membranes, although non-neuronal cell types appear normal. These membrane abnormalities develop in postmigratory embryonic neurons and subsequently worsen with further neuronal maturation, a finding evocative of the developmental dependence of DYT1 dystonia. These observations demonstrate that neurons have a unique requirement for nuclear envelope localized torsinA function and suggest that loss of this activity is a key molecular event in the pathogenesis of DYT1 dystonia.
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              The pathophysiology of primary dystonia.

              Co-contraction and overflow of EMG activity of inappropriate muscles are typical features of all dystonic movements whether voluntary or involuntary. Voluntary movements are slow and more variable than normal, and there is particular difficulty switching between component movements of a complex task. Reduced spinal cord and brainstem inhibition is common to many reflex studies (long-latency reflexes, cranial reflexes and reciprocal inhibition). These reflex abnormalities may contribute to the difficulties in voluntary movements but cannot be causal as they can occur outside the clinically involved territory. Clinical and neurophysiological studies have emphasized the possible role of sensory feedback in the generation of dystonic movements. Abnormalities of cortical and basal ganglia function have been described in functional imaging and neurophysiological studies of patients with dystonia and in animal models of primary dystonia. Studies of cortical function have shown reduced preparatory activity in the EEG before the onset of voluntary movements, whilst magnetic brain stimulation has revealed changes in motor cortical excitability. Functional imaging of the brain in primary dystonia has suggested reduced pallidal inhibition of the thalamus with consequent overactivity of medial and prefrontal cortical areas and underactivity of the primary motor cortex during movements. These findings are supported by preliminary neuronal recordings from the globus pallidus and the thalamus at the time of stereotaxic surgery in patients with dystonia. All this evidence suggests that primary dystonia results from a functional disturbance of the basal ganglia, particularly in the striatal control of the globus pallidus (and substantia nigra pars reticulata). This causes altered thalamic control of cortical motor planning and executive areas, and abnormal regulation of brainstem and spinal cord inhibitory interneuronal mechanisms.
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                Author and article information

                Journal
                Int J Mol Sci
                Int J Mol Sci
                ijms
                International Journal of Molecular Sciences
                MDPI
                1422-0067
                06 February 2020
                February 2020
                : 21
                : 3
                : 1073
                Affiliations
                [1 ]Department of Systems Medicine, Tor Vergata University of Rome, via Montpellier 1, 00133 Rome, Italy; dangelo@ 123456med.uniroma2.it (V.D.);
                [2 ]Santa Lucia Foundation, via del Fosso di Fiorano 64, 00143 Rome, Italy
                [3 ]Department of Biology and Biotechnology “Charles Darwin”, Sapienza University of Rome, Piazzale A. Moro 5, 00185 Rome, Italy stefano.biagioni@ 123456uniroma1.it (S.B.)
                Author notes
                Author information
                https://orcid.org/0000-0003-1544-3907
                Article
                ijms-21-01073
                10.3390/ijms21031073
                7037849
                32041188
                459067e3-8c67-4e96-b257-e51c077ff23c
                © 2020 by the authors.

                Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license ( http://creativecommons.org/licenses/by/4.0/).

                History
                : 27 December 2019
                : 01 February 2020
                Categories
                Article

                Molecular biology
                dystonia,striatum,d2 receptors,synapses,dopamine volume transmission
                Molecular biology
                dystonia, striatum, d2 receptors, synapses, dopamine volume transmission

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