Vimentin in the Central Nervous System

Intermediate filament proteins were identified by two-dimensional gel electrophoresis in urea extracts of rat optic nerves undergoing Wallerian degeneration and in cytoskeletal preparations of rat brain and spinal cord during postnatal development. The glial fibrillary acidic (GFA) protein and vimentin were the major optic nerve proteins following Wallerian degeneration. Vimentin was a major cytoskeletal component of newborn central nervous system (CNS) and then progressively decreased until it became barely identifiable in mature brain and spinal cord. The decrease of vimentin occurred concomitantly with an increase in GFA protein. A protein with the apparent molecular weight of 61,000 and isoelectric point of 5.6 was identified in both cytoskeletal preparations of brain and spinal cord, and in urea extracts of normal optic nerves. The protein disappeared together with the polypeptides forming the neurofilament triplet in degenerated optic nerves.     

Glycogen in the Marine Protozoon Parauronema acutum*

SYNOPSIS. The carbohydrate which accumulates in the cytoplasm of the marine protozoon, Parauronema acutum, during normal growth was isolated, purified and characterized chemically. The highly purified material yielded only glucose residues following hydrolysis in 0.6 N HCl for 3 h at 100 C; measurement of total carbohydrate by the phenol-sulfuric acid method and by treatment with amylo-glucosidase and glucose oxidase gave similar values. Aqueous solutions of the purified material reacted with iodine to form a complex which exhibited an absorption peak at 456 nm with a shift to 484 nm in the presence of 50% saturated (NH₄)₂SO₄. Digestion with α-amylase, β-amylase, and isoamylase yielded 71%, 45% and 8.3% hydrolysis, respectively. Treatment sequentially with both isoamylase and β-amylase gave complete hydrolysis of the polymer. The average chain length (CL) determined by the isoamylase procedure was 12. These observations are consistent with the view that the carbohydrate isolated from the protozoan is a polymer consisting of α-D-glucose residues arranged in chains containing α-(1→4) linkages with branch points containing α-(1→6) linkages occurring once on the average of ～ 12 glucose residues and, as such, is indistinguishable from glycogen isolated from mammalian sources.     

Riboflavin Homeostasis in the Central Nervous System

Abstract: The mechanisms by which riboflavin, which is not synthesized in mammals, enters and leaves brain, CSF, and choroid plexus were investigated by injecting [¹⁴C]riboflavin intravenously or intraventricularly. Tracer amounts of [¹⁴C]riboflavin with or without FMN were infused intravenously at a constant rate into normal, starved, or probenecid-pretreated rabbits. At 3 h, [¹⁴C]riboflavin readily entered choroid plexus and brain, and, to a much lesser extent, CSF. Over 85% of the [¹⁴C]riboflavin in brain and choroid plexus was present as [¹⁴C]FMN and [¹⁴C]FAD. The addition of 0.2 mmol/kg FMN to the infusate markedly depressed the relative entry of [¹⁴C]riboflavin into brain, choroid plexus, and, less so, CSF, whereas starvation increased the relative entry of [¹⁴C]riboflavin into brain and choroid plexus. After intraventricular injection (2 h), most of the [¹⁴C]riboflavin was extremely rapidly cleared from CSF into blood. Some of the [¹⁴C]riboflavin entered brain, where over 85% of the ¹⁴C was present as [¹⁴C]FMN plus [¹⁴C]FAD. The addition of 1.2³μmol FAD (which was rapidly hydrolyzed to riboflavin) to the injectate decreased the clearance of [¹⁴C]riboflavin from CSF and the phosphorylation of [¹⁴C]riboflavin in brain. Probenecid in the injectate also decreased the clearance of [¹⁴C]riboflavin from CSF. These results show that the control of entry and exit of riboflavin is the mechanism, at least in part, by which total riboflavin levels in brain cells and CSF are regulated. Penetration of riboflavin through the blood-brain barrier, saturable efflux of riboflavin from CSF, and saturable entry of riboflavin into brain cells are three distinct parts of the homeostatic system for total riboflavin in the central nervous system.     

Cytokine Actions in the Central Nervous System

Cytokines and chemokines have been implicated in contributing to the initiation, propagation and regulation of immune and inflammatory responses. Also, these soluble mediators have important roles in contributing to a wide array of neurological diseases such as multiple sclerosis, AIDS Dementia Complex, stroke and Alzheimers disease. Cytokines and chemokines are synthesized within the central nervous system by glial cells and neurons, and have modulatory functions on these same cells via interactions with specific cell-surface receptors. In this article, I will discuss the ability of glial cells and neurons to both respond to, and synthesize, a variety of cytokines. The emphasize will be on three select cytokines; interferon-gamma (IFN-γ), a cytokine with predominantly proinflammatory effects; interleukin-6 (IL-6), a cytokine with both pro- and anti-inflammatory properties; and transforming growth factor-beta (TGF-β), a cytokine with predominantly immunosuppressive actions. The significance of these cytokines to neurological diseases with an immunological component will be discussed.     

TWEAK and the Central Nervous System

Tumor necrosis factor-like weak inducer of apoptosis (TWEAK) is a member of the tumor necrosis factor superfamily that acts on responsive cells via binding to a cell surface receptor named fibroblast growth factor-inducible 14 (Fn14). TWEAK can regulate numerous cellular responses in vitro and in vivo. Recent studies have indicated that TWEAK and Fn14 are expressed in the central nervous system (CNS), and that in response to a variety of stimuli, including cerebral ischemia, there is an increase in TWEAK and Fn14 expression in perivascular astrocytes, microglia, endothelial cells, and neurons with subsequent increase in the permeability of the blood–brain barrier (BBB) and cell death. Furthermore, there is a growing body of evidence indicating that TWEAK induces the activation of the NF-κB in the CNS with release of proinflammatory cytokines and matrix metalloproteinases. In addition, inhibition of TWEAK activity by either treatment with a Fn14-Fc fusion protein or neutralizing anti-TWEAK antibodies has shown therapeutic efficacy in animal models of ischemic stroke, cerebral edema, and multiple sclerosis.     

A Novel Subtype of Prostacyclin Receptor in the Central Nervous System

Recently, in the course of our search for the prostacyclin receptor in the brain, we found a novel subtype, designated as IP2, which was finely discriminated by use of the specific ligand (15R)-16-m-tolyl-17,18,19,20-tetranorisocarbacyclin (15R-TIC) and specifically localized in the rostral part of the brain. In the present study, the tritiated compound 15R-[15-(3)H]TIC was synthesized and utilized for more specific research on IP2. The specificity of binding to rat brain regions was confirmed by use of several prostacyclin derivatives including 15S-TIC. Mapping of 15R- and 15S-[3H]TIC binding in adjacent pairs of frozen sections of rat brain demonstrated a quite similar pattern of distribution in almost all rostral brain regions, indicating that the regions may contain only the IP2 subtype. On the other hand, 15R-[3H]TIC binding was very faint as compared with 15S-[3H]TIC binding in the caudal medullary region. High densities of 15R-[3H]TIC binding sites were shown in the dorsal part of the lateral septal nucleus, thalamic nuclei, limbic structures, and some of the cortical regions. Scatchard plot analysis showed two components of high-affinity 15R-[3H]TIC binding in the rostral regions, one with a K(D) value at approximately 1 nM and the other with approximately 30 nM. These results strengthen our previous finding that a different subtype of prostacyclin receptor is expressed in the CNS, and the map with 15R-[3H]TIC obtained here could guide further studies on the molecular and functional properties of the IP2.     

Cytokine-Induced Inflammation in the Central Nervous System Revisited

Cytokines play an essential role as mediators of the immune response. They usually function as part of a network of interactive signals that either activate, enhance, or inhibit the ensuing reaction. An important contribution of this cytokine cascade is the induction of an inflammatory response that recruits and activates subsets of leukocytes that function as effector cells in the response to the sensitizing antigen. Proinflammatory cytokines activate endothelial cells (EC) to express adhesion molecules and induce the release of members of the chemokine family, thus focusing and directing the inflammatory response to sites of antigen recognition. However, the vasculature of the central nervous system (CNS) is highly specialized and restricts the access of components of the immune system to the CNS compartment. In this review, we address the question as to whether endothelial cells in the CNS respond differently to specific cytokines known to induce either a proinflammatory effect or a regulatory effect in systemic vascular beds.     

The Glycosphingolipid Hydrolases in the Central Nervous System

Glycosphingolipids are a large group of complex lipids particularly abundant in the outer layer of the neuronal plasma membranes. Qualitative and quantitative changes in glycosphingolipids have been reported along neuronal differentiation and aging. Their half-life is short in the nervous system and their membrane composition and content are the result of a complex network of metabolic pathways involving both the de novo synthesis in the Golgi apparatus and the lysosomal catabolism. In particular, most of the enzymes of glycosphingolipid biosynthesis and catabolism have been found also at the plasma membrane level. Their action could be responsible for the fine tuning of the plasma membrane glycosphingolipid composition allowing the formation of highly specialized membrane areas, such as the synapses and the axonal growth cones. While the correlation between the changes of GSL pattern and the modulation of the expression/activity of different glycosyltransferases during the neuronal differentiation has been widely discussed, the role of the glycohydrolytic enzymes in this process is still little explored. For this reason, in the present review, we focus on the main glycolipid catabolic enzymes β-hexosaminidases, sialidases, β-galactosidases, and β-glucocerebrosidases in the process of the neuronal differentiation.     

Electroneutral Cation-Chloride Cotransporters in the Central Nervous System

Several members of the cation-chloride cotransporter (solute carrier family 12, SLC12) gene family are expressed within the central nervous system, with one family member, the K+-Cl- cotransporter KCC2, exclusive to neurons. These transporters are best known for their roles in cell volume regulation and epithelial salt transport, but are increasingly receiving attention in neuroscience. In particular, intracellular chloride activity and hence the neuronal response to GABA and glycine appears to be determined by a balance between chloride efflux and influx through KCC2 and the Na+-K+-2Cl- cotransporter NKCC1, respectively. This relationship has important implications for neuronal development, sensory perception, neuronal excitability, and the response to neuronal injury. Finally, the association between loss of function in the K+-Cl- cotransporter KCC3, with a severe peripheral neuropathy associated with agenesis of the corpus callosum, has revealed an unexpected role for K+-Cl- cotransport in the development and/or maintenance of both the central and peripheral nervous systems.     

Central Nervous System Manifestations of Chickenpox

A study of 57 cases of affection of the central nervous system associated with chickenpox diagnosed and treated at The Hospital for Sick Children in Toronto between 1956 and 1967, inclusive, is presented. The commonest type, the cerebellar variety (50%), had an excellent prognosis. In the next commonest, the cerebral type (40%), the mortality rate was 35% but there was a low incidence of permanent sequelae in the surviving patients. A small group classed as aseptic meningitis was defined and one case of myelitis was reviewed.     

Prologue: Expressing the Central Nervous System

Neurochemical Research -