Tetraspanins as Potential Modulators of Glutamatergic Synaptic Function

Tetraspanins (Tspans) comprise a membrane protein family structurally defined by four transmembrane domains and intracellular N and C termini that is found in almost all cell types and tissues of eukaryotes. Moreover, they are involved in a bewildering multitude of diverse biological processes such as cell adhesion, motility, protein trafficking, signaling, proliferation, and regulation of the immune system. Beside their physiological roles, they are linked to many pathophysiological phenomena, including tumor progression regulation, HIV-1 replication, diabetes, and hepatitis. Tetraspanins are involved in the formation of extensive protein networks, through interactions not only with themselves but also with numerous other specific proteins, including regulatory proteins in the central nervous system (CNS). Interestingly, recent studies showed that Tspan7 impacts dendritic spine formation, glutamatergic synaptic transmission and plasticity, and that Tspan6 is correlated with epilepsy and intellectual disability (formerly known as mental retardation), highlighting the importance of particular tetraspanins and their involvement in critical processes in the CNS. In this review, we summarize the current knowledge of tetraspanin functions in the brain, with a particular focus on their impact on glutamatergic neurotransmission. In addition, we compare available resolved structures of tetraspanin family members to those of auxiliary proteins of glutamate receptors that are known for their modulatory effects.

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Plectin in the Central Nervous System and a Putative Role in Brain Astrocytes

Cells ◽

10.3390/cells10092353 ◽

2021 ◽

Vol 10 (9) ◽

pp. 2353

Author(s):

Maja Potokar ◽

Jernej Jorgačevski

Keyword(s):

Central Nervous System ◽

Nervous System ◽

Current Knowledge ◽

Cell Types ◽

Cellular Proteins ◽

Bidirectional Communication ◽

The Central Nervous System ◽

Brain And Spinal Cord ◽

The Brain

Plectin, a high-molecular-mass cytolinker, is abundantly expressed in the central nervous system (CNS). Currently, a limited amount of data about plectin in the CNS prevents us from seeing the complete picture of how plectin affects the functioning of the CNS as a whole. Yet, by analogy to its role in other tissues, it is anticipated that, in the CNS, plectin also functions as the key cytoskeleton interlinking molecule. Thus, it is likely involved in signalling processes, thereby affecting numerous fundamental functions in the brain and spinal cord. Versatile direct and indirect interactions of plectin with cytoskeletal filaments and enzymes in the cells of the CNS in normal physiological and in pathologic conditions remain to be fully addressed. Several pathologies of the CNS related to plectin have been discovered in patients with plectinopathies. However, in view of plectin as an integrator of a cohesive mesh of cellular proteins, it is important that the role of plectin is also considered in other CNS pathologies. This review summarizes the current knowledge of plectin in the CNS, focusing on plectin isoforms that have been detected in the CNS, along with its expression profile and distribution alongside diverse cytoskeleton filaments in CNS cell types. Considering that the bidirectional communication between neurons and glial cells, especially astrocytes, is crucial for proper functioning of the CNS, we place particular emphasis on the known roles of plectin in neurons, and we propose possible roles of plectin in astrocytes.

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The Roles of Lpar1 in Central Nervous System Disorders and Diseases

Frontiers in Neuroscience ◽

10.3389/fnins.2021.710473 ◽

2021 ◽

Vol 15 ◽

Author(s):

Dongqiong Xiao ◽

Xiaojuan Su ◽

Hu Gao ◽

Xihong Li ◽

Yi Qu

Keyword(s):

Central Nervous System ◽

Nervous System ◽

Cell Types ◽

Potential Therapeutic Target ◽

Cns Disorders ◽

The Central Nervous System ◽

Almost All ◽

G Protein Coupled ◽

Differentiation Gene ◽

The Brain

Lysophosphatidic acid receptor 1 (Lpar1), which is found in almost all human tissues but is most abundant in the brain, can couple to G protein-coupled receptors (GPCRs) and participate in regulating cell proliferation, migration, survival, and apoptosis. Endothelial differentiation gene-2 receptor (Edg2), the protein encoded by the Lpar1 gene, is present on various cell types in the central nervous system (CNS), such as neural stem cells (NSCs), oligodendrocytes, neurons, astrocytes, and microglia. Lpar1 deletion causes neurodevelopmental disorders and CNS diseases, such as brain cancer, neuropsychiatric disorders, demyelination diseases, and neuropathic pain. Here, we summarize the possible roles and mechanisms of Lpar1/Edg2 in CNS disorders and diseases and propose that Lpar1/Edg2 might be a potential therapeutic target for CNS disorders and diseases.

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Neural Stem Cells: What Happens When They Go Viral?

Viruses ◽

10.3390/v13081468 ◽

2021 ◽

Vol 13 (8) ◽

pp. 1468

Author(s):

Yashika S. Kamte ◽

Manisha N. Chandwani ◽

Alexa C. Michaels ◽

Lauren A. O’Donnell

Keyword(s):

Stem Cells ◽

Neural Stem Cells ◽

Viral Infections ◽

Wide Spectrum ◽

Cell Types ◽

Developmental Abnormalities ◽

Multipotent Progenitor Cells ◽

The Central Nervous System ◽

Simplex Virus ◽

The Brain

Viruses that infect the central nervous system (CNS) are associated with developmental abnormalities as well as neuropsychiatric and degenerative conditions. Many of these viruses such as Zika virus (ZIKV), cytomegalovirus (CMV), and herpes simplex virus (HSV) demonstrate tropism for neural stem cells (NSCs). NSCs are the multipotent progenitor cells of the brain that have the ability to form neurons, astrocytes, and oligodendrocytes. Viral infections often alter the function of NSCs, with profound impacts on the growth and repair of the brain. There are a wide spectrum of effects on NSCs, which differ by the type of virus, the model system, the cell types studied, and the age of the host. Thus, it is a challenge to predict and define the consequences of interactions between viruses and NSCs. The purpose of this review is to dissect the mechanisms by which viruses can affect survival, proliferation, and differentiation of NSCs. This review also sheds light on the contribution of key antiviral cytokines in the impairment of NSC activity during a viral infection, revealing a complex interplay between NSCs, viruses, and the immune system.

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The Microbiota–Gut–Brain Axis and Alzheimer Disease. From Dysbiosis to Neurodegeneration: Focus on the Central Nervous System Glial Cells

Journal of Clinical Medicine ◽

10.3390/jcm10112358 ◽

2021 ◽

Vol 10 (11) ◽

pp. 2358

Author(s):

Maria Grazia Giovannini ◽

Daniele Lana ◽

Chiara Traini ◽

Maria Giuliana Vannucchi

Keyword(s):

Alzheimer Disease ◽

Glial Cells ◽

Cell Types ◽

The Past ◽

The Central Nervous System ◽

Diseased State ◽

The Brain ◽

Alzheimer Disease Pathogenesis ◽

Brain Homeostasis

The microbiota–gut system can be thought of as a single unit that interacts with the brain via the “two-way” microbiota–gut–brain axis. Through this axis, a constant interplay mediated by the several products originating from the microbiota guarantees the physiological development and shaping of the gut and the brain. In the present review will be described the modalities through which the microbiota and gut control each other, and the main microbiota products conditioning both local and brain homeostasis. Much evidence has accumulated over the past decade in favor of a significant association between dysbiosis, neuroinflammation and neurodegeneration. Presently, the pathogenetic mechanisms triggered by molecules produced by the altered microbiota, also responsible for the onset and evolution of Alzheimer disease, will be described. Our attention will be focused on the role of astrocytes and microglia. Numerous studies have progressively demonstrated how these glial cells are important to ensure an adequate environment for neuronal activity in healthy conditions. Furthermore, it is becoming evident how both cell types can mediate the onset of neuroinflammation and lead to neurodegeneration when subjected to pathological stimuli. Based on this information, the role of the major microbiota products in shifting the activation profiles of astrocytes and microglia from a healthy to a diseased state will be discussed, focusing on Alzheimer disease pathogenesis.

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Comparisons of neuroinflammation, microglial activation, and degeneration of the locus coeruleus-norepinephrine system in APP/PS1 and aging mice

Journal of Neuroinflammation ◽

10.1186/s12974-020-02054-2 ◽

2021 ◽

Vol 18 (1) ◽

Author(s):

Song Cao ◽

Daniel W. Fisher ◽

Guadalupe Rodriguez ◽

Tian Yu ◽

Hongxin Dong

Keyword(s):

Spinal Cord ◽

Locus Coeruleus ◽

Microglial Activation ◽

Healthy Aging ◽

Cell Types ◽

Norepinephrine System ◽

Protective Processes ◽

The Central Nervous System ◽

Brain And Spinal Cord ◽

The Brain

Abstract Background The role of microglia in Alzheimer’s disease (AD) pathogenesis is becoming increasingly important, as activation of these cell types likely contributes to both pathological and protective processes associated with all phases of the disease. During early AD pathogenesis, one of the first areas of degeneration is the locus coeruleus (LC), which provides broad innervation of the central nervous system and facilitates norepinephrine (NE) transmission. Though the LC-NE is likely to influence microglial dynamics, it is unclear how these systems change with AD compared to otherwise healthy aging. Methods In this study, we evaluated the dynamic changes of neuroinflammation and neurodegeneration in the LC-NE system in the brain and spinal cord of APP/PS1 mice and aged WT mice using immunofluorescence and ELISA. Results Our results demonstrated increased expression of inflammatory cytokines and microglial activation observed in the cortex, hippocampus, and spinal cord of APP/PS1 compared to WT mice. LC-NE neuron and fiber loss as well as reduced norepinephrine transporter (NET) expression was more evident in APP/PS1 mice, although NE levels were similar between 12-month-old APP/PS1 and WT mice. Notably, the degree of microglial activation, LC-NE nerve fiber loss, and NET reduction in the brain and spinal cord were more severe in 12-month-old APP/PS1 compared to 12- and 24-month-old WT mice. Conclusion These results suggest that elevated neuroinflammation and microglial activation in the brain and spinal cord of APP/PS1 mice correlate with significant degeneration of the LC-NE system.

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Lipid Transport and Metabolism at the Blood-Brain Interface: Implications in Health and Disease

Frontiers in Physiology ◽

10.3389/fphys.2021.645646 ◽

2021 ◽

Vol 12 ◽

Author(s):

Fabien Pifferi ◽

Benoit Laurent ◽

Mélanie Plourde

Keyword(s):

Fatty Acids ◽

Neurodegenerative Diseases ◽

Current Knowledge ◽

Lipid Transport ◽

Omega 3 ◽

Blood Brain ◽

Brain Interface ◽

The Central Nervous System ◽

Health And Disease ◽

The Brain

Many prospective studies have shown that a diet enriched in omega-3 polyunsaturated fatty acids (n-3 PUFAs) can improve cognitive function during normal aging and prevent the development of neurocognitive diseases. However, researchers have not elucidated how n-3 PUFAs are transferred from the blood to the brain or how they relate to cognitive scores. Transport into and out of the central nervous system depends on two main sets of barriers: the blood-brain barrier (BBB) between peripheral blood and brain tissue and the blood-cerebrospinal fluid (CSF) barrier (BCSFB) between the blood and the CSF. In this review, the current knowledge of how lipids cross these barriers to reach the CNS is presented and discussed. Implications of these processes in health and disease, particularly during aging and neurodegenerative diseases, are also addressed. An assessment provided here is that the current knowledge of how lipids cross these barriers in humans is limited, which hence potentially restrains our capacity to intervene in and prevent neurodegenerative diseases.

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The HIV-1 Transgenic Rat: Relevance for HIV Noninfectious Comorbidity Research

Microorganisms ◽

10.3390/microorganisms8111643 ◽

2020 ◽

Vol 8 (11) ◽

pp. 1643

Author(s):

Frank Denaro ◽

Francesca Benedetti ◽

Myla D. Worthington ◽

Giovanni Scapagnini ◽

Christopher C. Krauss ◽

...

Keyword(s):

Neuronal Degeneration ◽

Cell Types ◽

Transgenic Rat ◽

Specific Cell ◽

Rat Tissues ◽

Local Production ◽

Specific Tissue ◽

Effective Models ◽

The Brain ◽

Hiv 1

HIV noninfectious comorbidities (NICMs) are a current healthcare challenge. The situation is further complicated as there are very few effective models that can be used for NICM research. Previous research has supported the use of the HIV-1 transgenic rat (HIV-1TGR) as a model for the study of HIV/AIDS. However, additional studies are needed to confirm whether this model has features that would support NICM research. A demonstration of the utility of the HIV-1TGR model would be to show that the HIV-1TGR has cellular receptors able to bind HIV proteins, as this would be relevant for the study of cell-specific tissue pathology. In fact, an increased frequency of HIV receptors on a specific cell type may increase tissue vulnerability since binding to HIV proteins would eventually result in cell dysfunction and death. Evidence suggests that observations of selective cellular vulnerability in this model are consistent with some specific tissue vulnerabilities seen in NICMs. We identified CXCR4-expressing cells in the brain, while specific markers for neuronal degeneration demonstrated that the same neural types were dying. We also confirm the presence of gp120 and Tat by immunocytochemistry in the spleen, as previously reported. However, we observed very rare positive cells in the brain. This underscores the point that gp120, which has been reported as detected in the sera and CSF, is a likely source to which these CXCR4-positive cells are exposed. This alternative appears more probable than the local production of gp120. Further studies may indicate some level of local production, but that will not eliminate the role of receptor-mediated pathology. The binding of gp120 to the CXCR4 receptor on neurons and other neural cell types in the HIV-1TGR can thus explain the phenomena of selective cell death. Selective cellular vulnerability may be a contributing factor to the development of NICMs. Our data indicate that the HIV-1TGR can be an effective model for the studies of HIV NICMs because of the difference in the regional expression of CXCR4 in rat tissues, thus leading to specific organ pathology. This also suggests that the model can be used in the development of therapeutic options.

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The Role of Microglia and Macrophages in CNS Homeostasis, Autoimmunity, and Cancer

Journal of Immunology Research ◽

10.1155/2017/5150678 ◽

2017 ◽

Vol 2017 ◽

pp. 1-12 ◽

Cited By ~ 34

Author(s):

Jie Yin ◽

Katherine L. Valin ◽

Michael L. Dixon ◽

Jianmei W. Leavenworth

Keyword(s):

Current Knowledge ◽

Complex Function ◽

Cell Types ◽

First Line ◽

Cns Disorders ◽

Cns Autoimmunity ◽

The Face ◽

The Central Nervous System ◽

Macrophage Subsets

Macrophages are major cell types of the immune system, and they comprise both tissue-resident populations and circulating monocyte-derived subsets. Here, we discuss microglia, the resident macrophage within the central nervous system (CNS), and CNS-infiltrating macrophages. Under steady state, microglia play important roles in the regulation of CNS homeostasis through the removal of damaged or unnecessary neurons and synapses. In the face of inflammatory or pathological insults, microglia and CNS-infiltrating macrophages not only constitute the first line of defense against pathogens by regulating components of innate immunity, but they also regulate the adaptive arms of immune responses. Dysregulation of these responses contributes to many CNS disorders. In this overview, we summarize the current knowledge regarding the highly diverse and complex function of microglia and macrophages during CNS autoimmunity—multiple sclerosis and cancer—malignant glioma. We emphasize how the crosstalk between natural killer (NK) cells or glioma cells or glioma stem cells and CNS macrophages impacts on the pathological processes. Given the essential role of CNS microglia and macrophages in the regulation of all types of CNS disorders, agents targeting these subsets are currently applied in preclinical and clinical trials. We believe that a better understanding of the biology of these macrophage subsets offers new exciting paths for therapeutic intervention.

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F-actin cytoskeletal organization in intervertebral disc health and disease

Biochemical Society Transactions ◽

10.1042/bst0350683 ◽

2007 ◽

Vol 35 (4) ◽

pp. 683-685 ◽

Cited By ~ 6

Author(s):

S. Li ◽

V.C. Duance ◽

E.J. Blain

Keyword(s):

Intervertebral Disc ◽

Protein Trafficking ◽

Current Knowledge ◽

Cell Types ◽

Filamentous Actin ◽

Cellular Events ◽

Disc Cells ◽

Health And Disease ◽

Cytoskeletal Networks ◽

Review Current

The cytoskeleton, which in most cell types, including the intervertebral disc described here, comprises microfilaments, microtubules and intermediate filaments, plays important functions in many fundamental cellular events, including cell division, motility, protein trafficking and secretion. The cytoskeleton is also critical for communication; for example, alterations to the architecture of the F-actin (filamentous actin) cytoskeletal networks can affect communication between the cells and the extracellular matrix, potentially compromising tissue homoeostasis. Although there are limited studies to date, this paper aims to review current knowledge on F-actin cytoskeletal element organization in intervertebral disc cells, how F-actin differs with pathology and its implications for mechanotransduction.

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Mitochondrial Heterogeneity in the Brain at the Cellular Level

Journal of Cerebral Blood Flow & Metabolism ◽

10.1097/00004647-199803000-00001 ◽

1998 ◽

Vol 18 (3) ◽

pp. 231-237 ◽

Cited By ~ 72

Author(s):

Ursula Sonnewald ◽

Leif Hertz ◽

Arne Schousboe

Keyword(s):

Amino Acid ◽

Current Knowledge ◽

Cell Types ◽

Cellular Level ◽

Mitochondrial Structure ◽

Cell Type Specific ◽

Mitochondrial Heterogeneity ◽

Specific Tissue ◽

And Function ◽

The Brain

Classically, compartmentation of glutamate metabolism in the brain is associated with the fact that neurons and glia exhibit distinct differences with regard to metabolism of this amino acid. The recent use of 13C-labeled compounds to study this metabolism in conjunction with the availability of cell type-specific tissue culture modes has led to the notion that such compartmentation may even be present in individual cell types, neurons as well as glia. To better understand and explain this, it is proposed that mitochondrial heterogeneity may exist resulting in tricarboxylic acid cycles with different properties regarding cycling rates and ratio as well as coupling to amino acid biosynthesis, primarily involving glutamate and aspartate. These hypotheses are evaluated in the light of current knowledge about mitochondrial structure and function.

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