Purification of an EH domain-binding protein from rat brain that modulates the gating of the rat ether-à-go-go channel

Mutations in the gene encoding ether-à-go-go (EAG) potassium channel impair the function of several classes of potassium currents, synaptic transmission, and learning in Drosophila. Absence of EAG abolishes the modulation of a broad group of potassium currents. EAG has been proposed to be a regulatory subunit of different potassium channels. To further explore this regulatory role we searched for signaling molecules that associate with EAG protein. We have purified a approximately 95-kDa protein from rat brain membranes that binds to EAG. When co-expressed in mammalian cells this protein coimmunoprecipites with EAG and alters the gating of EAG channels. Expression of this protein is regulated during neuronal differentiation. The protein is identical to the recently reported rat protein epsin, which is an EH domain-binding protein similar to the Xenopus mitotic phosphoprotein MP90. These results show that proteins of the epsin family are modulators of channel activity that may link signaling pathways, or the cell cycle, to EAG and thus to various potassium channel functions.     

Is there an energy conservation “system” in brain that protects against the consequences of energy depletion?

A poorly understood marked decrease (circa 50% of control) in local cerebral glucose utilization is caused by sublethal doses of NaCN. The decrease is global, occurring in essentially all brain regions and is entirely reversible within hours, leaving no obvious pathology. This event is not unique to NaCN in so far as a strikingly similar pattern of decreased glucose utilization occus with some other toxins. Nor can it be attributed to a direct action of NaCN since local application by microdialysis to the striatum produces a global depression. These results imply that some widely distributed system or substance is involved. We speculate the existence of a system possibly related to the reticular activating system that senses a fall in energy production and acts globally to make cells quiescent and thus would give some protection from excitotoxic driven damage.Special issue dedicated to Dr. Sidney Ochs.     

An immunohistochemical analysis of SERT in the blood–brain barrier of the male rat brain

5-Hydroxytryptamine (5-HT) was originally discovered as a vasoconstrictor. 5-HT lowers blood pressure when administered peripherally to both normotensive and hypertensive male rats. Because the serotonin transporter (SERT) can function bidirectionally, we must consider whether 5-HT can be transported from the bloodstream to the central nervous system (CNS) in facilitating the fall in blood pressure. The blood–brain barrier (BBB) is a highly selective barrier that restricts movement of substances from the bloodstream to the CNS and vice versa, but the rat BBB has not been investigated in terms of SERT expression. This requires us to determine whether the BBB of the rat, the species in which we first observed a fall in blood pressure to infused 5-HT, expresses SERT. We hypothesized that SERT is present in the BBB of the male rat. To test this hypothesis, over 500 blood vessels were sampled from coronal slices of six male rat brains. Immunofluorescence of these coronal slices was used to determine whether SERT and RecA-1 (an endothelial cell marker) colocalized to the BBB. Blood vessels were considered to be capillaries if they were between 1.5 and 23 µm (intraluminal diameter). SERT was identified in the largest pial vessels of the BBB (mean ± SEM = 228.70 ± 18.71 µm, N = 9) and the smallest capillaries (mean ± SEM = 2.75 ± 0.12 µm, N = 369). SERT was not identified in the endothelium of blood vessels ranging from 20 to 135 µm (N = 45). The expression of SERT in the rat BBB means that 5-HT entry into the CNS must be considered a potential mechanism when investigating 5-HT-induced fall in blood pressure.     

Distribution of acetylated α-tubulin in brain

Summary We studied the solubility properties of brain acetylated -tubulin, as well as the localization of this tubulin in brain tissue. Endogenous unpolymerized tubulin and cytoskeletal tubulin were fractionated after brain Triton-solubilization. Using the immunoblotting technique, we found that acetylated -tubulin was recovered in the cytoskeletal fraction, and that most (92%) of the acetylated microtubules of this fraction were depolymerized by cold/Ca²⁺ treatment. In another set of experiments, axonal and soma-dendritic preparations were found to have equivalent amounts of acetylated -tubulin. By immunogold electron microscopy, we established that acetylated microtubules are widely distributed in dendrites of the central nervous system.     

The nature of “internal sensations” of higher brain functions may be derived from the design rules for artificial machines that can produce them

Modeling various neuronal functions in search of emergent properties may achieve success when the gold standard of replicating the models in physical systems starts exhibiting some of these properties. Since very large number of functions can be modeled and need testing, we suggest an alternate method of examining higher brain functions: seeing them as internal sensations formed from their hypothetical basic units. Here, we explain the need to replicate the natural mechanism using electronic circuits, discuss some of the technical aspects and introduce some concepts for searching for properties of internal sensations evolving from them.     

Identification of the ATP·Mg-dependent protein phosphatase activator (Fa) as a synapsin I kinase that inhibits cross-linking of synapsin I with brain microtubules

The ATP·Mg-dependent protein phosphatase activating factor (Fa) has been identified and purified to near homogeneity from brain. In this report, as evidenced on SDS-polyacrylamide gel electrophoresis followed by autoradiography, factorFa has further been identified as a cAMP and Ca²⁺-independent brain kinase that could phosphorylate synapsin I, a neuronal protein that coats synaptic vesicles, binds to cytoskeleton, and is believed to be involved in the modulation of neurotransmission. Kinetic study further indicated that factorFa could phosphorylate synapsin I with a lowK _m value of about 2 µM and with a molar ratio of 1 mol of phosphate per mole of protein. Peptide mapping analysis revealed that factorFa specifically phosphorylated the tail region of synapsin I but on a unique site distinct from those phosphorylated by Ca²⁺/calmodulin-dependent protein kinase II and cAMP-dependent protein kinase, the two well-established synapsin I kinases. Functional study further revealed that factorFa could phosphorylate this unique specific site on the tail region of synapsin I and thereby inhibit cross-linking of synapsin I with microtubules. The results further suggest the possible involvement of factorFa as a synapsin I kinase in the regulation of axonal transport process of synaptic vesicles via the promotion of vesicles motility during neurotransmission.     

Breakdown of the blood–brain barrier to proteins in white matter of the developing brain following systemic inflammation

Compromised blood–brain barrier permeability resulting from systemic inflammation has been implicated as a possible cause of brain damage in fetuses and newborns and may underlie white matter damage later in life. Rats at postnatal day (P) 0, P8 and P20 and opossums (Monodelphis domestica) at P15, P20, P35, P50 and P60 and adults of both species were injected intraperitoneally with 0.2–10 mg/kg body weight of 055:B5 lipopolysaccharide. An acute-phase response occurred in all animals. A change in the permeability of the blood–brain barrier to plasma proteins during a restricted period of postnatal development in both species was determined immunocytochemically by the presence of proteins surrounding cerebral blood vessels and in brain parenchyma. Blood vessels in white matter, but not grey matter, became transiently permeable to proteins between 10 and 24 h after lipopolysaccharide injection in P0 and P8 rats and P35–P60 opossums. Brains of Monodelphis younger than P35, rats older than P20 and adults of both species were not affected. Permeability of the blood–cerebrospinal fluid (CSF) barrier to proteins was not affected by systemic inflammation for at least 48 h after intraperitoneal injection of lipopolysaccharide. These results show that there is a restricted period in brain development when the blood–brain barrier, but not the blood–CSF barrier, to proteins is susceptible to systemic inflammation; this does not appear to be attributable to barrier immaturity but to its stage of development and only occurs in white matter.This work was supported by NIH grant number R01 NS043949-01A1.     

Effects of β-endorphin on brain serotonin metabolism

Human β-endorphin (15 μg) administered intracisternally increased concentrations of serotonin (5HT) and its metabolite, 5-hydroxyindoleacetic. acid (5-HIAA), in brain stem and hypothalamus and decreased 5-HIAA concentrations in hippocampus. These data are compatible with the hypothesis that β-endorphin increases 5HT turnover in brain stem and hypothalamus and decreases 5HT turnover in hippocampus. β-endorphin increased in brain stem and hypothalamus and decreased in hippocampus the rate of pargyline-induced decline of 5-HIAA. β-endorphin decreased the rate of pargyline-induced accumulation of 5HT in all these brain regions. The probenecid-induced accumulation of 5-HIAA in brain stem was decreased by β-endorphin. These data are compatible with the hypothesis that β-endorphin increases release of 5HT from neurons in brain stem and hypothalamus and decreases release of 5HT from neurons in hippocampus. The data require further a hypothesis that β-endorphin either decreases 5HT reuptake in these three brain regions or increases 5-HIAA egress from brain.     

Effect of β-phenylethylamine on dopaminergic systems of the rat brain

The time course of changes in the dopamine concentration in dopaminergic neurons of the nigro-neostriatal and mesolimbic systems of the rat brain during 1 h after intraperitoneal injection of -phenylethylamine (100 mg/kg) was studied by quantitative fluorescence-histochemical analysis. The results showed that -phenylethylamine causes a marked fall in the dopamine level in neurons of dopaminergic systems of the brain. The dopamine level in the bodies of dopaminergic neurons changes more than in their axon terminals. The fall in the dopamine concentration in the dopaminergic systems of the brain during the first hour is irregular in character: in the terminals between 10 and 30 min and in the bodies between 30 and 45 min there is actually a temporary increase in the dopamine concentration. The rise in the dopamine concentration in the terminals coincides with a sharp fall in the dopamine level in the neuron bodies, and conversely, the fall in the dopamine concentration in the terminals after 30 min is accompanied by some increase in the dopamine concentration in the neuron bodies. The results suggest that the increase in motor activity described in the literature in animals after injection of -phenylethylamine is connected with its action on catecholaminergic, especially dopaminergic, brain systems.Institute of Biophysics, Academy of Sciences of the USSR, Pushchino-on-Oka. Translated from Neirofiziologiya, Vol. 11, No. 6, pp. 578–584, November–December, 1979.     

Culture of mouse brain capillary endothelial cell lines that express factor VIII, γ-glutamyl transpeptidase,and form junctional complexes in vitro

Summary The isolation and culture of cell lines from mouse brain capillary endothelium (MBE) is described. Cells migrating from collagenase-treated capillary fragments proliferated rapidly in the 1st wk of culture forming large epithelioid cobblestonelike colonies. The cells showed only marginal proliferation after 2 to 3 wk in culture, until peripheral cells migrated away from the colony which exhibited a marked degree of proliferation. These cells were trypsinized and subcultured to confluence. The cells can be maintained for well over 40 passages and seem to retain their endothelial morphology. The endothelial origin of these cells was demonstrated by positive immunoperoxidase reactivity with Factor VIII-related antigen, specific binding ofBandeiraea simplicifolia lectin and γ-glutamyl transpeptidase activity. Electron microscopic examination of the MBE cells showed junctional complexes including intermediate junctions, but no tight junctions. The overall ultrastructure indicates that a degree of dedifferentiation has occurred, the cells ultrastructurally resembling immature endothelium. An earlier investigation of cultured mouse brain endothelial cells reported a cell line that had lost many functional and structural characteristics. Our study demonstrates, as the previous one, that a certain degree of dedifferentiation needs to occur if MBE cells are to be maintained for long-term culture. However, the degree of dedifferentiation seems to be variable, depending in part on the culture conditions employed. This work was supported in part by grants from the National Health and Medical Research Council of Australia and the Telethon and Royal Perth Hospital Research Foundations.     

What brain signals are suitable for feedback controzl of deep brain stimulation in Parkinson's disease?

Feedback control of deep brain stimulation (DBS) in Parkinson's disease has great potential to improve efficacy, reduce side effects, and decrease the cost of treatment. In this, the timing and intensity of stimulation are titrated according to biomarkers that capture current clinical state. Stimulation may be at standard high frequency or intelligently patterned to directly modify specific pathological rhythms. The search for and validation of appropriate feedback signals are therefore crucial. Signals recorded from the DBS electrode currently appear to be the most promising source of feedback. In particular, beta-frequency band oscillations in the local field potential recorded at the stimulation target may capture variation in bradykinesia and rigidity across patients, but this remains to be confirmed within patients. Biomarkers that reliably reflect other impairments, such as tremor, also need to be established. Finally, whether brain signals are causally important needs to be established before stimulation can be specifically patterned rather than delivered at empirically defined high frequency.     

Biosynthesis of serotonin in Raphé nuclei of rat brain: effect of p-chlorophenylalanine

The activity of tryptophan hydroxylase (EC 1.99.1.4) in the region of the raphé nuclei of rat brain was higher than that of any other brain area. The content of serotonin and the rate of serotonin synthesis were also highest in the raphé nuclei. Following the administration of p-chlorophenylalanine the injection of tryptophan and pargyline increased the content of serotonin in the region of the raphé nuclei of rat brain. The results suggest that the raphé nuclei retained the capacity to hydroxyl-late tryptophan to some extent after the injection of p-chlorophenylalanine.     

Isolation and characterization of bovine brain myelin distribution of 5′-nucleotidase

Myelin was isolated from bovine brain by several published procedures and modifications of these procedures. High activity of the myelin marker (2,3-cyclic nucleotide 3-phosphohydrolase) and low activity of contaminants markers in white matter homogenates in respect to cerebral cortex showed the white matter to be better than the cerebral cortex or the whole brain for myelin isolation. A procedure is described for the preparation of purified myelin from bovine white matter which yielded a content of protein (40%), myelin marker (51%), and 5-nucleotidase (25%) in purified myelin higher than by any used method. Acetylcholinesterase or succinate dehydrogenase was lower than 7% of its activity in the white matter homogenate, and monoamine oxidase and NADPH: cytochrome c reductase were not recovered in myelin fraction. Morphologically, myelin fraction was shown to mainly consist of multilamellar membranes of different sizes. Sodium dodecyl sulphate polyacrylamide gel electrophoresis of myelin fraction showed a characteristic protein pattern of myelin. When our procedure was applied to frozen white matter, lower protein (32%) and myelin marker (34%) and similar 5-nucleotidase activity (24%) were recovered in myelin, increasing its recovery in denser fractions of white matter.     

Alpha synuclein is transported into and out of the brain by the blood–brain barrier

Alpha-synuclein (α-Syn), a small protein with multiple physiological and pathological functions, is one of the dominant proteins found in Lewy Bodies, a pathological hallmark of Lewy body disorders, including Parkinson's disease (PD). More recently, α-Syn has been found in body fluids, including blood and cerebrospinal fluid, and is likely produced by both peripheral tissues and the central nervous system. Exchange of α-Syn between the brain and peripheral tissues could have important pathophysiologic and therapeutic implications. However, little is known about the ability of α-Syn to cross the blood–brain barrier (BBB). Here, we found that radioactively labeled α-Syn crossed the BBB in both the brain-to-blood and the blood-to-brain directions at rates consistent with saturable mechanisms. Low-density lipoprotein receptor-related protein-1 (LRP-1), but not p-glycoprotein, may be involved in α-Syn efflux and lipopolysaccharide (LPS)-induced inflammation could increase α-Syn uptake by the brain by disrupting the BBB.     

Hypothermia-induced tyrosine phosphorylation of SIRPα in the brain

Signal regulatory protein α (SIRPα) is a neuronal membrane protein that undergoes tyrosine phosphorylation in the brain of mice in response to forced swim (FS) stress in cold water, and this response is implicated in regulation of depression-like behavior in the FS test. We now show that subjection of mice to the FS in warm (37 °C) water does not induce the tyrosine phosphorylation of SIRPα in the brain. The rectal temperature (T(rec) ) of mice was reduced to 27° to 30 °C by performance of the FS for 10 min in cold water, whereas it was not affected by the same treatment in warm water. The level of tyrosine phosphorylation of SIRPα in the brain was increased by administration of ethanol or picrotoxin, starvation, or cooling after anesthesia, all of which also induced hypothermia. Furthermore, the tyrosine phosphorylation of SIRPα in cultured hippocampal neurons was induced by lowering the temperature of the culture medium. CD47, a ligand of SIRPα, as well as Src family kinases or SH2 domain-containing protein phosphatase 2 (Shp2), might be important for the basal and the hypothermia-induced tyrosine phosphorylation of SIRPα. Hypothermia is therefore likely an important determinant of both the behavioral immobility and tyrosine phosphorylation of SIRPα observed in the FS test.