Your search keyword '"striosome"' showing total 16 results

1. Dissecting Striosome Circuitry and the Mechanisms of Tardive Dyskinesia

Author

McGregor, Matthew Mark, Kreitzer, Anatol C1, McGregor, Matthew Mark, McGregor, Matthew Mark, Kreitzer, Anatol C1, and McGregor, Matthew Mark

Abstract

The basal ganglia are a group of interconnected, subcortical nuclei that mediate a wide array of behavioral functions. The primary input nucleus of the basal ganglia, the striatum, is a region implicated in behaviors ranging from motor control, reward learning, decision making, habit formation, to social interaction. How these diverse behavioral functions map onto various striatal cell types and circuit connections remains a major question within the basal ganglia field. Classical models of striatal circuitry that divide output neurons into populations called the direct and indirect pathways have proven extremely useful in understanding how the striatum mediates function such as movement initiation and behavioral reinforcement. Furthermore, such models have played a foundational role in understanding the pathophysiology of disorders linked to the basal ganglia, such as Parkinson’s disease and Huntington’s disease. These models, however, struggle to explain how the striatum mediates other well-established functions, and can even lead to contradictory predictions of behavior in other types of disease. To explore how alternative models of striatal circuitry might be used to fill in these gaps, we took two parallel approaches. First, we investigated whether striosome and matrix neurons—an alternative model for dividing striatal neurons—differ in the electrophysiological properties and synaptic connectivity. Early anatomical work suggested that striosome and matrix may represent two parallel circuits, relaying limbic and motor information to downstream nuclei, respectively. However, recent attempts to genetically isolate these population cast doubt upon these earlier findings. Using a developmental approach to isolate striosome and matrix neurons, we found that these population receive differing cortical input consistent with early anatomical studies. Furthermore, we determined that striosome and matrix differ in how they process cortical input and where they project inf

Published

2022

2. Dissecting Striosome Circuitry and the Mechanisms of Tardive Dyskinesia

Author

McGregor, Matthew Mark, Kreitzer, Anatol C1, McGregor, Matthew Mark, McGregor, Matthew Mark, Kreitzer, Anatol C1, and McGregor, Matthew Mark

Abstract

The basal ganglia are a group of interconnected, subcortical nuclei that mediate a wide array of behavioral functions. The primary input nucleus of the basal ganglia, the striatum, is a region implicated in behaviors ranging from motor control, reward learning, decision making, habit formation, to social interaction. How these diverse behavioral functions map onto various striatal cell types and circuit connections remains a major question within the basal ganglia field. Classical models of striatal circuitry that divide output neurons into populations called the direct and indirect pathways have proven extremely useful in understanding how the striatum mediates function such as movement initiation and behavioral reinforcement. Furthermore, such models have played a foundational role in understanding the pathophysiology of disorders linked to the basal ganglia, such as Parkinson’s disease and Huntington’s disease. These models, however, struggle to explain how the striatum mediates other well-established functions, and can even lead to contradictory predictions of behavior in other types of disease. To explore how alternative models of striatal circuitry might be used to fill in these gaps, we took two parallel approaches. First, we investigated whether striosome and matrix neurons—an alternative model for dividing striatal neurons—differ in the electrophysiological properties and synaptic connectivity. Early anatomical work suggested that striosome and matrix may represent two parallel circuits, relaying limbic and motor information to downstream nuclei, respectively. However, recent attempts to genetically isolate these population cast doubt upon these earlier findings. Using a developmental approach to isolate striosome and matrix neurons, we found that these population receive differing cortical input consistent with early anatomical studies. Furthermore, we determined that striosome and matrix differ in how they process cortical input and where they project inf

Published

2022

3. Generation of a MOR-CreER knock-in mouse line to study cells and neural circuits involved in mu opioid receptor signaling

Author

Okunomiya, Taro and Okunomiya, Taro

Published

2020

4. Functionally Distinct Connectivity of Developmentally Targeted Striosome Neurons.

Author

McGregor, Matthew M, McGregor, Matthew M, McKinsey, Gabriel L, Girasole, Allison E, Bair-Marshall, Chloe J, Rubenstein, John LR, Nelson, Alexandra B, McGregor, Matthew M, McGregor, Matthew M, McKinsey, Gabriel L, Girasole, Allison E, Bair-Marshall, Chloe J, Rubenstein, John LR, and Nelson, Alexandra B

Abstract

One long-standing model of striatal function divides the striatum into compartments called striosome and matrix. While some anatomical evidence suggests that these populations represent distinct striatal pathways with differing inputs and outputs, functional investigation has been limited by the methods for identifying and manipulating these populations. Here, we utilize hs599CreER mice as a new tool for targeting striosome projection neurons and testing their functional connectivity. Extending anatomical work, we demonstrate that striosome neurons receive greater synaptic input from prelimbic cortex, whereas matrix neurons receive greater input from primary motor cortex. We also identify functional differences in how striosome and matrix neurons process excitatory input, providing the first electrophysiological method for delineating striatal output neuron subtypes. Lastly, we provide the first functional demonstration that striosome neurons are the predominant striatal output to substantia nigra pars compacta dopamine neurons. These results identify striosome and matrix as functionally distinct striatal pathways.

Published

2019

5. Functionally Distinct Connectivity of Developmentally Targeted Striosome Neurons.

Author

McGregor, Matthew M, McGregor, Matthew M, McKinsey, Gabriel L, Girasole, Allison E, Bair-Marshall, Chloe J, Rubenstein, John LR, Nelson, Alexandra B, McGregor, Matthew M, McGregor, Matthew M, McKinsey, Gabriel L, Girasole, Allison E, Bair-Marshall, Chloe J, Rubenstein, John LR, and Nelson, Alexandra B

Abstract

One long-standing model of striatal function divides the striatum into compartments called striosome and matrix. While some anatomical evidence suggests that these populations represent distinct striatal pathways with differing inputs and outputs, functional investigation has been limited by the methods for identifying and manipulating these populations. Here, we utilize hs599CreER mice as a new tool for targeting striosome projection neurons and testing their functional connectivity. Extending anatomical work, we demonstrate that striosome neurons receive greater synaptic input from prelimbic cortex, whereas matrix neurons receive greater input from primary motor cortex. We also identify functional differences in how striosome and matrix neurons process excitatory input, providing the first electrophysiological method for delineating striatal output neuron subtypes. Lastly, we provide the first functional demonstration that striosome neurons are the predominant striatal output to substantia nigra pars compacta dopamine neurons. These results identify striosome and matrix as functionally distinct striatal pathways.

Published

2019

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Author

Yoshizawa, Tomohiko, 31429, Yoshizawa, Tomohiko, and 31429

Abstract

doctoral thesis

Published

2018

7. Quantitative Analyses of the Projection of Individual Neurons from the Midline Thalamic Nuclei to the Striosome and Matrix Compartments of the Rat Striatum

Author

Unzai, Tomo and Unzai, Tomo

Published

2018

8. Striatal Vulnerability in Huntington’s Disease : Neuroprotection Versus Neurotoxicity

Author

Morigaki, Ryoma, Goto, Satoshi, Morigaki, Ryoma, and Goto, Satoshi

Abstract

Huntington’s disease (HD) is an autosomal dominant neurodegenerative disease caused by the expansion of a CAG trinucleotide repeat encoding an abnormally long polyglutamine tract (PolyQ) in the huntingtin (Htt) protein. In HD, striking neuropathological changes occur in the striatum, including loss of medium spiny neurons and parvalbumin-expressing interneurons accompanied by neurodegeneration of the striosome and matrix compartments, leading to progressive impairment of reasoning, walking and speaking abilities. The precise cause of striatal pathology in HD is still unknown; however, accumulating clinical and experimental evidence suggests multiple plausible pathophysiological mechanisms underlying striatal neurodegeneration in HD. Here, we review and discuss the characteristic neurodegenerative patterns observed in the striatum of HD patients and consider the role of various huntingtin-related and striatum-enriched proteins in neurotoxicity and neuroprotection.

Published

2017

9. Clinicopathological Phenotype and Genetics of X-Linked Dystonia–Parkinsonism (XDP; DYT3; Lubag)

Author

Kawarai, Toshitaka, Morigaki, Ryoma, Kaji, Ryuji, Goto, Satoshi, Kawarai, Toshitaka, Morigaki, Ryoma, Kaji, Ryuji, and Goto, Satoshi

Abstract

X-linked dystonia–parkinsonism (XDP; OMIM314250), also referred to as DYT3 dystonia or “Lubag” disease, was first described as an endemic disease in the Philippine island of Panay. XDP is an adult-onset movement disorder characterized by progressive and severe dystonia followed by overt parkinsonism in the later years of life. Among the primary monogenic dystonias, XDP has been identified as a transcriptional dysregulation syndrome with impaired expression of the TAF1 (TATA box-binding protein associated factor 1) gene, which is a critical component of the cellular transcription machinery. The major neuropathology of XDP is progressive neuronal loss in the neostriatum (i.e., the caudate nucleus and putamen). XDP may be used as a human disease model to elucidate the pathomechanisms by which striatal neurodegeneration leads to dystonia symptoms. In this article, we introduce recent advances in the understanding of the interplay between pathophysiology and genetics in XDP.

Published

2017

10. Conditional targeting of medium spiny neurons in the striatal matrix

Author

Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, Kullander, Klas, Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, and Kullander, Klas

Abstract

The striatum serves as the main input to the basal ganglia, and is key for the regulation of motor behaviors, compulsion, addiction, and various cognitive and emotional states. Its deterioration is associated with degenerative disorders such as Huntington's disease. Despite its apparent anatomical uniformity, it consists of intermingled cell populations, which have precluded straightforward anatomical sub-classifications adhering to functional dissections. Approximately 95% of the striatal neurons are inhibitory projection neurons termed medium spiny neurons (MSNs). They are commonly classified according to their expression of either dopamine receptor D1 or D2, which also determines their axonal projection patterns constituting the direct and indirect pathway in the basal ganglia. lmmunohistochemical patterns have further indicated compartmentalization of the striatum to the striosomes and the surrounding matrix, which integrate MSNs of both the D1 and D2 type. Here, we present a transgenic mouse line, Gpr101-Cre, with Cre recombinase activity localized to matrix D1 and D2 MSNs. Using two Gpr101-Cre founder lines with different degrees of expression in the striatum, we conditionally deleted the vesicular inhibitory amino acid transporter (VIAAT), responsible for storage of GABA and glycine in synaptic vesicles. Partial ablation of VIAAT (in similar to 36% of MSNs) resulted in elevated locomotor activity compared to control mice, when provoked with the monoamine reuptake inhibitor cocaine. Near complete targeting of matrix MSNs led to profoundly changed motor behaviors, which increased in severity as the mice aged. Moreover, these mice had exaggerated muscle rigidity, retarded growth, increased rate of spontaneous deaths, and defective memory. Therefore, our data provide a link between dysfunctional GABA signaling of matrix MSNs to specific behavioral alterations, which are similar to the symptoms of Huntington's disease.

Published

2015

11. Conditional targeting of medium spiny neurons in the striatal matrix

Author

Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, Kullander, Klas, Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, and Kullander, Klas

Abstract

The striatum serves as the main input to the basal ganglia, and is key for the regulation of motor behaviors, compulsion, addiction, and various cognitive and emotional states. Its deterioration is associated with degenerative disorders such as Huntington's disease. Despite its apparent anatomical uniformity, it consists of intermingled cell populations, which have precluded straightforward anatomical sub-classifications adhering to functional dissections. Approximately 95% of the striatal neurons are inhibitory projection neurons termed medium spiny neurons (MSNs). They are commonly classified according to their expression of either dopamine receptor D1 or D2, which also determines their axonal projection patterns constituting the direct and indirect pathway in the basal ganglia. lmmunohistochemical patterns have further indicated compartmentalization of the striatum to the striosomes and the surrounding matrix, which integrate MSNs of both the D1 and D2 type. Here, we present a transgenic mouse line, Gpr101-Cre, with Cre recombinase activity localized to matrix D1 and D2 MSNs. Using two Gpr101-Cre founder lines with different degrees of expression in the striatum, we conditionally deleted the vesicular inhibitory amino acid transporter (VIAAT), responsible for storage of GABA and glycine in synaptic vesicles. Partial ablation of VIAAT (in similar to 36% of MSNs) resulted in elevated locomotor activity compared to control mice, when provoked with the monoamine reuptake inhibitor cocaine. Near complete targeting of matrix MSNs led to profoundly changed motor behaviors, which increased in severity as the mice aged. Moreover, these mice had exaggerated muscle rigidity, retarded growth, increased rate of spontaneous deaths, and defective memory. Therefore, our data provide a link between dysfunctional GABA signaling of matrix MSNs to specific behavioral alterations, which are similar to the symptoms of Huntington's disease.

Published

2015

12. Conditional targeting of medium spiny neurons in the striatal matrix

Author

Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, Kullander, Klas, Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, and Kullander, Klas

Abstract

The striatum serves as the main input to the basal ganglia, and is key for the regulation of motor behaviors, compulsion, addiction, and various cognitive and emotional states. Its deterioration is associated with degenerative disorders such as Huntington's disease. Despite its apparent anatomical uniformity, it consists of intermingled cell populations, which have precluded straightforward anatomical sub-classifications adhering to functional dissections. Approximately 95% of the striatal neurons are inhibitory projection neurons termed medium spiny neurons (MSNs). They are commonly classified according to their expression of either dopamine receptor D1 or D2, which also determines their axonal projection patterns constituting the direct and indirect pathway in the basal ganglia. lmmunohistochemical patterns have further indicated compartmentalization of the striatum to the striosomes and the surrounding matrix, which integrate MSNs of both the D1 and D2 type. Here, we present a transgenic mouse line, Gpr101-Cre, with Cre recombinase activity localized to matrix D1 and D2 MSNs. Using two Gpr101-Cre founder lines with different degrees of expression in the striatum, we conditionally deleted the vesicular inhibitory amino acid transporter (VIAAT), responsible for storage of GABA and glycine in synaptic vesicles. Partial ablation of VIAAT (in similar to 36% of MSNs) resulted in elevated locomotor activity compared to control mice, when provoked with the monoamine reuptake inhibitor cocaine. Near complete targeting of matrix MSNs led to profoundly changed motor behaviors, which increased in severity as the mice aged. Moreover, these mice had exaggerated muscle rigidity, retarded growth, increased rate of spontaneous deaths, and defective memory. Therefore, our data provide a link between dysfunctional GABA signaling of matrix MSNs to specific behavioral alterations, which are similar to the symptoms of Huntington's disease.

Published

2015

13. Postsynaptic Density Protein 95 in the Striosome and Matrix Compartments of the Human Neostriatum

Author

Morigaki, Ryoma, Goto, Satoshi, Morigaki, Ryoma, and Goto, Satoshi

Abstract

The human neostriatum consists of two functional subdivisions referred to as the striosome (patch) and matrix compartments. The striosome-matrix dopamine systems play a central role in cortico-thalamo-basal ganglia circuits, and their involvement is thought to underlie the genesis of multiple movement and behavioral disorders, and of drug addiction. Human neuropathology also has shown that striosomes and matrix have differential vulnerability patterns in several striatal neurodegenerative diseases. Postsynaptic density protein 95 (PSD-95), also known as disks large homolog 4, is a major scaffolding protein in the postsynaptic densities of dendritic spines. PSD-95 is now known to negatively regulate not only N-methyl-D-aspartate glutamate signaling, but also dopamine D1 signals at sites of postsynaptic transmission. Accordingly, a neuroprotective role for PSD-95 against dopamine D1 receptor (D1R)-mediated neurotoxicity in striatal neurodegeneration also has been suggested. Here, we used a highly sensitive immunohistochemistry technique to show that in the human neostriatum, PSD-95 is differentially concentrated in the striosome and matrix compartments, with a higher density of PSD-95 labeling in the matrix compartment than in the striosomes. This compartment-specific distribution of PSD-95 was strikingly complementary to that of D1R. In addition to the possible involvement of PSD-95-mediated synaptic function in compartment-specific dopamine signals, we suggest that the striosomes might be more susceptible to D1R-mediated neurotoxicity than the matrix compartment. This notion may provide new insight into the compartment-specific vulnerability of MSNs in striatal neurodegeneration.

Published

2015

14. Conditional targeting of medium spiny neurons in the striatal matrix

Author

Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, Kullander, Klas, Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, and Kullander, Klas

Abstract

The striatum serves as the main input to the basal ganglia, and is key for the regulation of motor behaviors, compulsion, addiction, and various cognitive and emotional states. Its deterioration is associated with degenerative disorders such as Huntington's disease. Despite its apparent anatomical uniformity, it consists of intermingled cell populations, which have precluded straightforward anatomical sub-classifications adhering to functional dissections. Approximately 95% of the striatal neurons are inhibitory projection neurons termed medium spiny neurons (MSNs). They are commonly classified according to their expression of either dopamine receptor D1 or D2, which also determines their axonal projection patterns constituting the direct and indirect pathway in the basal ganglia. lmmunohistochemical patterns have further indicated compartmentalization of the striatum to the striosomes and the surrounding matrix, which integrate MSNs of both the D1 and D2 type. Here, we present a transgenic mouse line, Gpr101-Cre, with Cre recombinase activity localized to matrix D1 and D2 MSNs. Using two Gpr101-Cre founder lines with different degrees of expression in the striatum, we conditionally deleted the vesicular inhibitory amino acid transporter (VIAAT), responsible for storage of GABA and glycine in synaptic vesicles. Partial ablation of VIAAT (in similar to 36% of MSNs) resulted in elevated locomotor activity compared to control mice, when provoked with the monoamine reuptake inhibitor cocaine. Near complete targeting of matrix MSNs led to profoundly changed motor behaviors, which increased in severity as the mice aged. Moreover, these mice had exaggerated muscle rigidity, retarded growth, increased rate of spontaneous deaths, and defective memory. Therefore, our data provide a link between dysfunctional GABA signaling of matrix MSNs to specific behavioral alterations, which are similar to the symptoms of Huntington's disease.

Published

2015

15. Conditional targeting of medium spiny neurons in the striatal matrix

Author

Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, Kullander, Klas, Reinius, Björn, Blunder, Martina, Brett, Frances M., Eriksson, Anders, Patra, Kalicharan, Jonsson, Jörgen, Jazin, Elena, and Kullander, Klas

Abstract

The striatum serves as the main input to the basal ganglia, and is key for the regulation of motor behaviors, compulsion, addiction, and various cognitive and emotional states. Its deterioration is associated with degenerative disorders such as Huntington's disease. Despite its apparent anatomical uniformity, it consists of intermingled cell populations, which have precluded straightforward anatomical sub-classifications adhering to functional dissections. Approximately 95% of the striatal neurons are inhibitory projection neurons termed medium spiny neurons (MSNs). They are commonly classified according to their expression of either dopamine receptor D1 or D2, which also determines their axonal projection patterns constituting the direct and indirect pathway in the basal ganglia. lmmunohistochemical patterns have further indicated compartmentalization of the striatum to the striosomes and the surrounding matrix, which integrate MSNs of both the D1 and D2 type. Here, we present a transgenic mouse line, Gpr101-Cre, with Cre recombinase activity localized to matrix D1 and D2 MSNs. Using two Gpr101-Cre founder lines with different degrees of expression in the striatum, we conditionally deleted the vesicular inhibitory amino acid transporter (VIAAT), responsible for storage of GABA and glycine in synaptic vesicles. Partial ablation of VIAAT (in similar to 36% of MSNs) resulted in elevated locomotor activity compared to control mice, when provoked with the monoamine reuptake inhibitor cocaine. Near complete targeting of matrix MSNs led to profoundly changed motor behaviors, which increased in severity as the mice aged. Moreover, these mice had exaggerated muscle rigidity, retarded growth, increased rate of spontaneous deaths, and defective memory. Therefore, our data provide a link between dysfunctional GABA signaling of matrix MSNs to specific behavioral alterations, which are similar to the symptoms of Huntington's disease.

Published

2015

16. Molecular dissection and anatomical basis of dystonia : X-linked recessive dystonia-parkinsonism (DYT3)

Author

Kaji, Ryuji, Goto, Satoshi, Tamiya, Gen, Ando, Satoshi, Makino, Satoshi, Lee, LV, Kaji, Ryuji, Goto, Satoshi, Tamiya, Gen, Ando, Satoshi, Makino, Satoshi, and Lee, LV

Abstract

Pathological findings in dystonia have been unclear. X-linked recessive dystonia-parkinsonism (XDP, DYT3), endemic in the Panay island, the Philippines, is characterized by the clinical onset with dystonia followed by parkinsonism. It provides a unique opportunity to explore the anatomical basis of dystonia, because it has discernible pathological changes even at its early phase of dystonia. After extensive searches for the anatomical basis in XDP, we found selective loss of striosomal neurons in the striatum in dystonic patients’ brain. Because striosomal neurons inhibit nigrostriatal dopaminergic neurons via GABAergic innervation, the striosomal lesion could account for dopamine excess in the striatum, which in turn causes a hyperkinetic state or dystonia. We also identified the causative gene as one of the general transcription factor genes, TAF1. XDP has certain similarities to Huntington disease not only in pathological and clinical findings, but also the molecular mechanism, which disturbs expression of genes essential for striatal neurons, such as DRD2. Therapeutic intervention may become possible through pharmacological measures that affect gene expression.

Published

2005