Heterogeneous vascular permeability and alternative diffusion barrier in sensory circumventricular organs of adult mouse brain

Morita, Shoko; Furube, Eriko; Mannari, Tetsuya; Okuda, Hiromichi; Tatsumi, Kouko; Wanaka, Akio; Miyata, Seiji

doi:10.1007/s00441-015-2207-7

Cited by 61 publications

(105 citation statements)

References 64 publications

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“…The distribution of laminin immunopositivity was similar to the distribution of “leaky” blood–brain barrier as described by Morita et al (). The separation of the glial and vascular basal laminae and the “leaky” vessels mutually depend on each other: a minimal perivascular space is required to receive the product of extravasation—and the extravasation inhibits the fusion of basal laminae.…”

Section: Discussionsupporting

confidence: 83%

“…Pekny () found that in the perivascular astrocytes GFAP is necessary for supporting the blood–brain barrier. In the GFAP‐rich lateral part of OVLT Morita et al () found occludin, claudin, and ZO‐1 in the capillaries and astrocytes. Therefore, these astrocytes may have a role in controlling the penetration of extravasated substances into the surrounding brain tissue.…”

Section: Discussionmentioning

confidence: 98%

“…In the “middle triangular area” of OVLT and in the core of SFO similar gradual alterations are found in the vascular immunolabeling following a double staining against β‐dystroglycan and laminin (Section 4.5, for the SFO see Pócsai & Kálmán, ). The most “leaky” vessels are in the “core” of SFO (e.g., Morita et al, ) and in the middle of OVLT in its vascular subdivision (e.g., Prager‐Khoutorsky & Bourque, ).…”

Section: Discussionmentioning

confidence: 99%

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Three‐plane description of astroglial populations of OVLT subdivisions in rat: Tanycyte connections to distant parts of third ventricle

Kálmán

Oszwald

Pócsai

2019

J of Comparative Neurology

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This study demonstrates glial and gliovascular markers of organon vasculosum laminae terminalis (OVLT) in three planes. The distribution of glial markers displayed similarities to the subfornical organ. There was an inner part with vimentin‐ and nestin‐immunopositive glia whereas GFAP and the water‐channel aquaporin 4 were found at the periphery. This separation indicates different functions of the two regions. The presence of nestin may indicate stem cell‐capabilities whereas aquaporin 4 has been reported to promote the osmoreceptor function. Glutamine synthetase immunoreactivity was sparse like in the area postrema and subfornical organ. The laminin and β‐dystroglycan immunolabelings altered along the vessels such as in the subfornical organ indicating altering gliovascular relations. The different subdivisions of OVLT received glial processes of different origins. The posterior periventricular zone contained short vimentin‐immunopositive processes from the ependyma of the adjacent surface of the third ventricle. The lateral periventricular zone received forceps‐like process systems from the anterolateral part of the third ventricle. Most interestingly, the “dorsal cap” received a mixed group of long GFAP‐ and vimentin‐immunopositive processes from a distant part of the third ventricle. The processes may have two functions: a guidance for newly produced cells like radial glia in immature brain and/or a connection between distant parts of the third ventricle and OVLT.

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Section: Discussionsupporting

confidence: 83%

Section: Discussionmentioning

confidence: 98%

Section: Discussionmentioning

confidence: 99%

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Three‐plane description of astroglial populations of OVLT subdivisions in rat: Tanycyte connections to distant parts of third ventricle

Kálmán

Oszwald

Pócsai

2019

J of Comparative Neurology

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“…The approach of using lymphoid cells and T cells from GFP-transgenic mice to trace the anatomical localization revealed a more extensive relationship between these cells and cells of the CNS. The abundant localization in the ME and CVOs is not unexpected, since these structures are devoid of the BBB and in contact with the circulation (Morita et al, 2015). However, the question arises if the localization in perivascular spaces and the brain parenchyma is an epiphenomenon of the adoptive transfer approach in Rag2 −/− mice or part of a naturally occurring process.…”

Section: Discussionmentioning

confidence: 99%

Expansion of brain T cells in homeostatic conditions in lymphopenic Rag2−/− mice

Song

Nicholson

Clark

et al. 2016

Brain, Behavior, and Immunity

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The concept of the brain as an immune privileged organ is rapidly evolving in light of new findings outlining the sophisticated relationship between the central nervous and the immune systems. The role of T cells in brain development and function, as well as modulation of behavior has been demonstrated by an increasing number of studies. Moreover, recent studies have redefined the existence of a brain lymphatic system and the presence of T cells in specific brain structures, such as the meninges and choroid plexus. Nevertheless, much information is needed to further the understanding of brain T cells and their relationship with the central nervous system under non-inflammatory conditions. In the present study we employed the Rag2−/− mouse model of lymphocyte deficiency and reconstitution by adoptive transfer to study the temporal and anatomical expansion of T cells in the brain under homeostatic conditions. Lymphopenic Rag2−/− mice were reconstituted with 10 million lymphoid cells and studied at one, two and four weeks after transfer. Moreover, lymphoid cells and purified CD4+ and CD8+ T cells from transgenic GFP expressing mice were used to define the neuroanatomical localization of transferred cells. T cell numbers were very low in the brain of reconstituted mice up to one week after transfer and significantly increased by 2 weeks, reaching wild type values at 4 weeks after transfer. CD4+ T cells were the most abundant lymphocyte subtype found in the brain followed by CD8+ T cells and lastly B cells. Furthermore, proliferation studies showed that CD4+ T cells expand more rapidly than CD8+ T cells. Lymphoid cells localize abundantly in meningeal structures, choroid plexus, and circumventricular organs. Lymphocytes were also found in vascular and perivascular spaces and in the brain parenchyma across several regions of the brain, in particular in structures rich in white matter content. These results provide proof of concept that the brain meningeal system, as well as vascular and perivascular spaces, are homing sites of lymphocytes and suggest the possibility of a brain specific T cell subtype.

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“…3 Thus, studies in mice show penetration of circulating markers such as fluorescein isothiocyanate, or higher molecular weight bovine serum albumin or dextrans permeating core regions more rapidly than peripheral subdivisions of sensory CVOs. 1,3-5 Furthermore, the altered blood-brain barrier within the sensory CVOs is not uniform in nature; fenestrated capillary endothelium is found throughout the sensory CVOs, whereas capillary tight junctions are absent in core regions but plentiful in more peripheral parts of these CVOs.…”

Section: The S En Sory C Vosmentioning

confidence: 99%

From sensory circumventricular organs to cerebral cortex: Neural pathways controlling thirst and hunger

McKinley

Denton

Ryan

et al. 2019

J Neuroendocrinology

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Much progress has been made during the past 30 years with respect to elucidating the neural and endocrine pathways by which bodily needs for water and energy are brought to conscious awareness through the generation of thirst and hunger. One way that circulating hormones influence thirst and hunger is by acting on neurones within sensory circumventricular organs (CVOs). This is possible because the subfornical organ and organum vasculosum of the lamina terminalis (OVLT), the sensory CVOs in the forebrain, and the area postrema in the hindbrain lack a normal blood‐brain barrier such that neurones within them are exposed to blood‐borne agents. The neural signals generated by hormonal action in these sensory CVOs are relayed to several sites in the cerebral cortex to stimulate or inhibit thirst or hunger. The subfornical organ and OVLT respond to circulating angiotensin II, relaxin and hypertonicity to drive thirst‐related neural pathways, whereas circulating amylin, leptin and possibly glucagon‐like peptide‐1 act at the area postrema to influence neural pathways inhibiting food intake. As a result of investigations using functional brain imaging techniques, the insula and anterior cingulate cortex, as well as several other cortical sites, have been implicated in the conscious perception of thirst and hunger in humans. Viral tracing techniques show that the anterior cingulate cortex and insula receive neural inputs from thirst‐related neurones in the subfornical organ and OVLT, with hunger‐related neurones in the area postrema having polysynaptic efferent connections to these cortical regions. For thirst, initially, the median preoptic nucleus and, subsequently, the thalamic paraventricular nucleus and lateral hypothalamus have been identified as likely sites of synaptic links in pathways from the subfornical organ and OVLT to the cortex. The challenge remains to identify the links in the neural pathways that relay signals originating in sensory CVOs to cortical sites subserving either thirst or hunger.

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Heterogeneous vascular permeability and alternative diffusion barrier in sensory circumventricular organs of adult mouse brain

Cited by 61 publications

References 64 publications

Three‐plane description of astroglial populations of OVLT subdivisions in rat: Tanycyte connections to distant parts of third ventricle

Three‐plane description of astroglial populations of OVLT subdivisions in rat: Tanycyte connections to distant parts of third ventricle

Expansion of brain T cells in homeostatic conditions in lymphopenic Rag2−/− mice

From sensory circumventricular organs to cerebral cortex: Neural pathways controlling thirst and hunger

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