Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

Keynote webinar | Spotlight on medication adherence

LIVE: Thursday 27th June 2024, 18:00-19:30 (CEST)
Join our expert panel to discover why you need to understand the drivers of non-adherence in your patients, and how you can optimize medication adherence in your clinics to drastically improve patient outcomes.
ADVANCED SEARCH
Log in
Top
Brain Structure and Function
Published in: Brain Structure and Function 9/2018

Open Access 01-12-2018 | Original Article

Striosome-based map of the mouse striatum that is conformable to both cortical afferent topography and uneven distributions of dopamine D1 and D2 receptor-expressing cells

Authors: Yuta Miyamoto, Sachiko Katayama, Naoki Shigematsu, Akinori Nishi, Takaichi Fukuda

Published in: Brain Structure and Function | Issue 9/2018

Login to get access

Abstract

The striatum is critically involved in execution of appropriate behaviors, but its internal structures remain unmapped due to its unique structural organization, leading to ambiguity when interpreting heterogeneous properties of striatal neurons that differ by location. We focused on site-specific diversity of striosomes/matrix compartmentalization to draw the striatum map. Five types of striosomes were discriminated according to diverse immunoreactivities for the µ-opioid receptor, substance P (SP) and enkephalin, and each type occupied a particular domain inside the striatum. Furthermore, there was an additional domain lacking striosomes. This striosome-free space was located at the dorsolateral region and received afferents preferentially from the primary motor and sensory cortices, whereas the striosome-rich part received afferents from associational/limbic cortices, with topography inside both innervations. The proportion of dopamine D1 receptor-expressing, presumptive striatonigral neurons was approximately 70% in SP-positive striosomes, 40% in SP-deficient striosomes, 30% in the striosome-free space, and 50% in the matrix. In contrast, the proportion of D2 receptor-expressing, presumptive striatopallidal neurons was complementary to that of D1 receptor-expressing cells, indicating a close relationship between the map and the direct and indirect parallel circuitry. Finally, the most caudal part of the striatum lacked compartmentalization and consisted of three lamina characterized by intense and mutually exclusive immunoreactivities for SP and enkephalin. This tri-laminar part also received specific afferents from the cortex. The newly obtained map will facilitate broad fields of research in the basal ganglia with higher resolution of the three-dimensional anatomy of the striatum.
Appendix
Available only for authorised users
Literature
Bateup H, Svenningsson P, Kuroiwa M, Gong S, Nishi A, Heintz N, Greengard P (2008) Differential effects of psychostimulants and antipsychotics on DARPP-32 phosphorylation in striatonigral and striatopallidal neurons. Nat Neurosci 11:932–939CrossRef
Bloem B, Huda R, Sur M, Graybiel AM (2017) Two-photon imaging in mice shows striosomes and matrix have overlapping but differential reinforcement-related responses. eLife 6:e32353CrossRef
Breuer O, Lawhorn C, Miller T, Smith DM, Brown LL (2005) Functional architecture of the mammalian striatum: mouse vasculature and striosome organization and their anatomic relationship. Neurosci Lett 385:198–203CrossRef
Crittenden JR, Graybiel AM (2011) Basal ganglia disorders associated with imbalances in the striatal striosome and matrix compartments. Front Neuroanat 5:Article 59CrossRef
Desban M, Kemel ML, Glowinski J, Gauchy C (1993) Spatial organization of patch and matrix compartments in the rat striatum. Neuroscience 57:661–671CrossRef
DiFeliceantonio AG, Marbrouk OS, Kennedy RT, Berridge KC (2012) Enkephalin surges in dorsal neostriatum as a signal to eat. Curr Biol 22:1918–1924CrossRef
Eblen F, Graybiel AM (1995) Highly restricted origin of prefrontal cortical inputs to striosomes in the macaque monkey. J Neurosci 15:5999–6013CrossRef
Flaherty AW, Graybiel AM (1993) Output architecture of the primate putamen. J Neurosci 13:3222–3237CrossRef
Friedman A, Homma D, Gibb L, Amemori K, Rubin SJ, Hood AS, Riad MH, Graybiel AM (2015) A corticostriatal path targeting striosomes controls decision-making under conflict. Cell 161:1320–1333CrossRef
Fujiyama F, Sohn J, Nakano T, Furuta T, Nakamura KC, Matsuda W, Kaneko T (2011) Exclusive and common targets of neostriatofugal projections of rat striosome neurons: a single neuron-tracing study using a viral vector. Eur J Neurosci 33:668–677CrossRef
Fukuda T (2009) Network architecture of gap junction-coupled neuronal linkage in the striatum. J Neurosci 29:1235–1243CrossRef
Fukuda T, Kosaka T (2000) Gap junctions linking the dendritic network of GABAergic interneurons in the hippocampous. J Neurosci 20:1510–1528CrossRef
Fukuda T, Aika Y, Heizmann CW, Kosaka T (1998) GABAergic axon terminals at perisomatic and dendritic inhibitory sites show different immunoreactivities against two GAD isoforms, GAD67 and GAD65, in the mouse hippocampus: a digitized quantitative analysis. J Comp Neurol 395:177–194CrossRef
Gangarossa G, Espallergues J, Mailly P, De Bundel D, de Kerchove d’Exaerde A, Hervé D, Girault J-A, Valjent E, Krieger P (2013) Spatial distribution of D1R- and D2R-expressing medium-sized spiny neurons differs along the rostro-caudal axis of the mouse dorsal striatum. Front Neur Circ 7:article 124
Gerfen CR (1984) The neostriatal mosaic: compartmentalization of corticostriatal input and striatonigral output system. Nature 311:461–463CrossRef
Gerfen CR (1985) The neostriatal mosaic. I. Compartmental organization of projections from the striatum to the substantia nigra in the rat. J Comp Neurol 236:454–476CrossRef
Gerfen CR, Baimbridge KG, Miller JJ (1985) The neostriatal mosaic: compartmental distribution of calcium-binding protein and parvalbumin in the basal ganglia of the rat and monkey. Proc Natl Acad Sci USA 82:8780–8784CrossRef
Gerfen CR, Engber TM, Mahan LC, Susei Z, Chase TN, Monsma FJ Jr, Sibley DR (1990) D2 dopamine receptor-regulated gene expression of striatonigral and striatopallidal neurons. Science 250:1429–1432CrossRef
Graybiel AM (2008) Habits, rituals, and the evaluative brain. Annu Rev Neurosci 31:359–387CrossRef
Graybiel AM, Ragsdale CW (1978) Histochemically distinct compartments in the striatum of human, monkey, and cat demonstrated by acetylthiocholinesterase staining. Proc Natl Acad Sci USA 75:5723–5725CrossRef
Graybiel AM, Ragsdale CW, Yoneoka ES, Elde RP (1981) An immunohistochemical study of enkephalins and other neuropeptides in the striatum of the cat with evidence that the opiate peptides are arranged to form mosaic patterns in register with the striosomal compartments visible by acetylcholinesterase staining. Neuroscience 6:377–397CrossRef
Groves PM, Martone M, Young SJ, Armstrong DM (1988) Three-dimensional pattern of enkephalin-like immunoreactivity in the caudate nucleus of the cat. J Neurosci 8:92–900CrossRef
Herkenham M, Pert CB (1981) Mosaic distribution of opiate receptors, parafascicular projections and acetylcholinesterase in rat striatum. Nature 291:415–418CrossRef
Hintiryan H, Foster NN, Bowman I, Bay M, Song MY, Gou L, Yamashita S, Bienkowski MS, Zingg B, Zhu M, Yang XW, Shin JC, Toga AW, Dong HW (2016) The mouse cortico-striatal projectome. Nat Neurosci 19:1100–1114CrossRef
Hunnicutt B, Jongbloets BC, Birdsong WT, Gertz K, Zhong H, Mao T (2016) A comprehensive excitatory input map of the striatum reveals novel functional organization. eLife 5:e19103CrossRef
Kawaguchi Y, Wilson CJ, Emson PC (1989) Intracellular recording of identified neostriatal patch and matrix spiny cells in a slice preparation preserving cortical inputs. J Neurophysiol 62:1052–1068CrossRef
Kimchi EY, Laubach M (2009a) Dynamic encoding of action selection by the medial striatum. J Neurosci 29:3148–3159CrossRef
Kimchi EY, Laubach M (2009b) The dorsomedial striatum reflects response bias during learning. J Neurosci 29:14891–14902CrossRef
Lee T, Kaneko T, Taki K, Mizuno N (1997) Preprodynorphin-, preproenkephalin-, and preprotachykinin-expressing neurons in the rat neostriatum: an analysis by immunocytochemistry and retrograde tracing. J Comp Neurol 386:229–244CrossRef
Liu F-C, Graybiel AM (1992) Heterogeneous development of calbindin-D28k expression in the striatal matrix. J Comp Neurol 320:304–322CrossRef
Lopez-Huerta VG, Nakano Y, Bausenwein J, Jaidar O, Lazarus M, Cherassse Y, Garcia-Munoz M, Arbuthnott G (2016) The neostriatum: two entities, one structure? Brain Struct Funct 221:1737–1749CrossRef
Manley MS, Younog SJ, Groves PM (1994) Compartmental organization of the peptide network in the human caudate nucleus. J Chem Neuroanat 7:191–201CrossRef
McGeorge AJ, Faull RM (1989) The organization of the projection from the cerebral cortex to the striatum in the rat. Neuroscience 29:503–537CrossRef
Mikula S, Parrish SK, Trimmer JS, Jones EG (2009) Complete 3D visualization of primate striosomes by KChIP1 immunostaining. J Comp Neurol 514:507–517CrossRef
Miyamoto Y, Fukuda T (2015) Immunohistochemical study on the neuronal diversity and three-dimensional organization of the mouse entopeduncular nucleus. Neurosci Res 94:37–49CrossRef
Parent A (1990) Extrinsic connections of the basal ganglia. Trends Neurosci 13:254–258CrossRef
Pennartz CM, Berke JD, Graybiel AM, Ito R, Lansink CS, van der Meer M, Redish AD, Smith KS, Voorn P (2009) Corticostriatal interactions during learning, memory processing, and decision making. J Neurosci 29:12831–12838CrossRef
Penny G, Wilson CJ, Kitai ST (1988) Relationship of the axonal and dendritic geometry of spiny projection neurons to the compartmental organization of the neostriatum. J Comp Neurol 269:275–289CrossRef
Prensa L, Parent A (2001) The nigrostriatal pathway in the rat: a single-axon study of the relationship between dorsal and ventral tier nigral neurons and the striosome/matrix striatal compartments. J Neurosci 21:7247–7260CrossRef
Prensa L, Giménez-Amaya JM, Parent A (1999) Chemical heterogeneity of the striosomal compartment in the human striatum. J Comp Neurol 413:603–618CrossRef
Shan Q, Christie MJ, Balleine BW (2015) Plasticity in striatopallidal projection neurons mediates the acquisition of habitual actions. Eur J Neurosci 42:2097–2104CrossRef
Smith JB, Klug JR, Ross DL, Callaway EM, Gerfen CR, Jin X (2016) Genetic-based dissection unveils the inputs and outputs of striatal patch and matrix compartments. Neuron 91:1069–1084CrossRef
Stephenson-Jones M, Yu K, Ahrens S, Tucciarone JM, van Huijstee AN, Mejia LA, Penzo MA, Tai L-H, Wilbrecht L, Li B (2016) A basal ganglia circuit for evaluating action outcomes. Nature 539:289–293CrossRef
Sterio DC (1984) The unbiased estimation of number and sizes of arbitrary particles using the disector. J Microsc 134:127–136CrossRef
Surmeier DJ, Ding J, Day M, Wang Z, Shen W (2007) D1 and D2 dopamine-receptor modulation of striatal glutamatergic signaling in striatal medium spiny neurons. Trends Neurosci 30:228–235CrossRef
Tai AX, Cassidy RM, Kromer LF (2013) EphA7 expression identifies a unique neuronal compartment in the rat striatum. J Comp Neurol 521:2663–2679CrossRef
Tajima K, Fukuda T (2013) Region-specific diversity of striosomes in the mouse striatum revealed by the differential immunoreactivities for mu-opioid receptor, substance P, and enkephalin. Neuroscience 241:215–228CrossRef
Thorn CA, Atallah H, Howe M, Graybiel AM (2010) Differential dynamics of activity changes in dorsolateral and dorsomedial striatal loops during learning. Neuron 66:781–795CrossRef
Tokuno H, Takada M, Kaneko T, Shigemoto R, Mizuno N (1996) Patchy distribution of substance P receptor immunoreactivity in the developing rat striatum. Dev Brain Res 95:107–117CrossRef
Valjent E, Bertran-Gonzalez J, Hervé D, Fisone G, Girault J-A (2009) Looking BAC at striatal signaling: cell-specific analysis in new transgenic mice. Trends Neurosci 32:538–547CrossRef
Voorn P, Vanderschuren LJMJ, Groenewegen HJ, Robbins TW, Pennartz MA (2004) Putting a spin on the dorsal-ventral divide of the striatum. Trends Neurosci 27:468–474CrossRef
Wall NR, De La Parra M, Callaway EM, Kreitzer AC (2013) Differential innervation of direct and indirect-pathway striatal projection neurons. Neuron 79:347–360CrossRef
Yin HH, Knowlton BJ, Balleine BW (2004) Lesions of dorsolateral striatum preserve outcome expectancy but disrupt habit formation in instrumental learning. Eur J Neurosci 19:181–189CrossRef
Yin HH, Mulcare SP, Hilário MRF, Clouse E, Holloway T, Davis MI, Hansson AC, Lovinger DM, Costa RM (2009) Dynamic reorganization of striatal circuits during the acquisition and consolidation of a skill. Nat Neurosci 12:333–341CrossRef
Metadata
Title
Striosome-based map of the mouse striatum that is conformable to both cortical afferent topography and uneven distributions of dopamine D1 and D2 receptor-expressing cells
Authors
Yuta Miyamoto
Sachiko Katayama
Naoki Shigematsu
Akinori Nishi
Takaichi Fukuda
Publication date
01-12-2018
Publisher
Springer Berlin Heidelberg
Published in
Brain Structure and Function / Issue 9/2018
Print ISSN: 1863-2653
Electronic ISSN: 1863-2661
DOI
https://doi.org/10.1007/s00429-018-1749-3

Other articles of this Issue 9/2018

Brain Structure and Function 9/2018 Go to the issue

Original Article

Interactive histogenesis of axonal strata and proliferative zones in the human fetal cerebral wall

Original Article

Whole mouse brain structural connectomics using magnetic resonance histology

Original Article

Activation in the auditory pathway of the gerbil studied with 18F-FDG PET: effects of anesthesia

Original Article

Radial glial elements in the cerebral cortex of the lesser hedgehog tenrec

Original Article

Distinct and complementary functions of rho kinase isoforms ROCK1 and ROCK2 in prefrontal cortex structural plasticity

Original Article

Establishing the cognitive signature of human brain networks derived from structural and functional connectivity