Subcellular Distribution of Ependymins in Goldfish Brain Measured by Radioimmunoassay

Goldfish CNS was fractionated by differential and density gradient centrifugation. The fractions obtained were characterized by marker enzymes typical of various subcellular organelles. They were further analyzed by radioimmunoassay for their contents of ependymins, two CNS glycoproteins known to participate in biochemical reactions after learning events. Ependymins were shown to be major constituents of the soluble cytoplasm (5.6% of the total protein content). The nuclear fraction was virtually devoid of ependymins (0.6% of protein). Small amounts were observed in the crude synaptosomal and microsomal fractions (1.0 and 3.5%, respectively). The highest steady-state concentration of ependymins, however, was measured in the brain extracellular fluid (15.6% of the protein), including the CSF. The specificity of the distribution was examined by intracerebroventricular injection of 125I-labeled ependymins as exogenous marker substances. No indication of an artificial redistribution of the radiolabel during homogenization and fractionation was obtained. The exogenous analogues of ependymins were, however, incorporated in vivo into organelles recovered in the nuclear and crude synaptosomal fractions. Our results suggest that ependymins may interact with synaptic membranes from the extracellular fluid, although so far no evidence for a specific receptor-type binding site could be obtained in vitro.     

A Radioimmunoassay for Ependymins β and γ: Two Goldfish Brain Proteins Involved in Behavioral Plasticity

Abstract: A radioimmunoassay (RIA) using ¹²⁵I-labeled antigen was developed for the quantitative determination of two goldfish brain proteins (ependymins β and γ). The proteins were isolated from the cerebrospinal fluid (CSF) and cells of the ependymal zone surrounding goldfish brain ventricles. The turnover rates of β and γ were previously shown to be specifically enhanced after the animals successfully acquired a new pattern of swimming behavior. Femtomole quantities of ependymin β were measurable by the RIA. In applications of the assay, β and γ ependymins were found to have common immunological properties, since ¹²⁵I-β-antigen bound to antibody could be displaced by unlabeled ependymin γ as well as ependymin β but not by a variety of other proteins including several purified glycoproteins isolated from goldfish brain. The ependymins were shown to constitute 14% of the total protein content of the brain extracellular fluid and also to be present as a minor component of the serum proteins (0.3%). Ependymins β and γ have an immunological reactivity in these fractions that can be increased by a factor of 30 on heating. The data suggest that the antigenicity of the molecules is highly masked, and that it may require some unraveling of the quaternary structure of the proteins before maximal interaction with the antisera becomes possible.     

Structural and Metabolic Relationships Between Goldfish Brain Glycoproteins Participating in Functional Plasticity of the Central Nervous System

Ependymins beta and gamma (MW 32,000 and 26,000 daltons) are two secreted goldfish brain glycoproteins that exhibit a specifically enhanced turnover rate when the animals successfully acquire a new pattern of swimming behaviour. Both proteins are bound identically to concanavalin A and can be isolated from brain extracellular fluid and from brain cytoplasm by lectin affinity chromatography. Radioimmunoassay data, using purified 125I-labeled ependymins and antisera directed against ependymin beta or ependymin gamma, show complete cross-reactivity between the two proteins. It is demonstrated by Scatchard-plot analysis that the antisera recognize identical immunological determinants in both proteins. The amino acid composition of the ependymins is similar, and several identical polypeptide fragments are obtained after limited proteolysis with Staphylococcus aureus protease. The proteins are capable of forming complexes of the compositions gamma 2, beta gamma, and beta 2. A protease present in the extracellular fluid of goldfish brain promotes proteolysis of ependymin beta to ependymin gamma. The finding that ependymin gamma is physiologically derived from ependymin beta suggests the possibility that ependymin beta might exert its biological function during consolidation of new behavioural patterns via smaller polypeptide fragments.     

In Vitro Protein Synthesis in the Goldfish Retinotectal Pathway During Regeneration: Evidence for Specific Axonal Proteins of Retinal Origin in the Optic Nerve

Four proteins with molecular weights of 58,000 can be separated as a linear array by two-dimensional gel electrophoresis. They are highly concentrated in the goldfish optic nerve and are designated as ON1, ON2, ON3, and ON4. Proteins ON1 and ON2 are undetectable in the optic nerve after disconnection and their concentration is gradually restored during regeneration. In vitro incubations of retinas, optic nerves, or tecta in the presence of [35S]methionine indicate that proteins ON1 and ON2 are of retinal origin. The labeling rate of these proteins in the retina increases fourfold after optic nerve crush whereas the overall labeling rate in the retina remains largely constant. Their synthesis cannot be detected in tissues devoid of retinal ganglion cells. This is consistent with the view that ON1 and ON2 are synthesized by retinal ganglion cells and are consequently of neuronal origin in the optic nerve. In contrast, similar experiments indicate that ON3 and ON4 are of nonneuronal origin. They are synthesized in the optic nerve in the absence of retinal ganglion cells.     

Subcellular Distribution of Tyrosine Hydroxylase in Some Catecholaminergic Rat Brain Areas Determined by a Quantitative Immunoblot Assay

The subcellular distribution of the protein tyrosine hydroxylase (TH) after fractionation of rat brain tissue was studied by a sensitive technique of immunoblot quantification in the dopaminergic nigrostriatal and the dorsal noradrenergic pathways and in the ventrolateral medulla. This repartition indicates that in all catecholaminergic regions of the cell bodies studied, the contribution of the nerve endings to the total TH amount is very low (less than 7%), in contrast to that observed in the terminal fields. The correlative subcellular determination of the TH amount and activity in the same tissue could be a useful approach for studying experimentally induced mechanisms of catecholamine synthesis modulation in different brain catecholaminergic pathways.     

Localization and Subcellular Distribution of N-Copine in Mouse Brain

Abstract : N -Copine is a novel protein with two C2 domains. Its expression is brain specific and up-regulated by neuronal activity such as kainate stimulation and tetanus stimulation evoking hippocampal CA1 long-term potentiation. We examined the localization and subcellular distribution of N -copine in mouse brain. In situ hybridization analysis showed that N -copine mRNA was expressed exclusively in neurons of the hippocampus and in the main and accessory olfactory bulb, where various forms of synaptic plasticity and memory formation are known to occur. In immunohistochemical analyses, N -copine was detected mainly in the cell bodies and dendrites in the neurons, whereas presynaptic proteins such as synaptotagmin I and rab3A were detected in the regions where axons pass through. In fractionation experiments of brain homogenate, N -copine was associated with the membrane fraction in the presence of Ca²⁺ but not in its absence. As a GST-fusion protein with the second C2 domain of N -copine showed Ca²⁺ -dependent binding to phosphatidylserine, this domain was considered to be responsible for the Ca²⁺ -dependent association of N -copine with the membrane. Thus, N -copine may have a role as a Ca²⁺ sensor in postsynaptic events, in contrast to the known roles of "double C2 domain-containing proteins," including synaptotagmin I, in presynaptic events.     

In Vitro Synthesis of Polypeptides of Moderately Large Size by Poly(A)-Containing Messenger RNA from Postmortem Human Brain and Mouse Brain

Studies were undertaken to optimize the conditions for isolation and in vitro translation of poly(A)-containing mRNA from human postmortem brain. The comparison of several methods for preparation of mRNA from frozen mouse brain indicated that although the yield of mRNA was increased using polysomes prepared in the presence of ribonucleoside vanadyl complexes and subsequently extracted with guanidinium thiocyanate, the translation products were indistinguishable from those synthesized by total cellular RNA directly extracted from tissue with guanidinium thiocyanate. The oligo d(T)-cellulose-purified poly(A)-containing mRNA preparations were translated in vitro in a rabbit reticulocyte lysate in the presence of L-[35S]methionine. Messenger RNA from frozen mouse brain stimulated protein synthesis from 9- to 20-fold over endogenous mRNA. Over 450 polypeptides were reproducibly synthesized and separated by two-dimensional polyacrylamide gel electrophoresis (PAGE); size classes up to 130,000 daltons were present. Direct extraction of RNA from frozen human cerebral cortex and cerebellum with guanidinium thiocyanate followed by oligo d(T)-cellulose chromatography yielded 1.8 micrograms/g and 2.0 micrograms/g, respectively, of poly(A)-containing mRNA; this represents a two- to fourfold increase over our earlier results. In the rabbit reticulocyte translation system human brain mRNA stimulated protein synthesis nearly threefold over endogenous mRNA. Compared with earlier studies, the number of newly synthesized polypeptides was increased by 30%. Over 300 species were separated by two-dimensional PAGE, and size classes up to 130,000 daltons were present, as compared to 70,000 in an earlier report. The polypeptides synthesized by human cerebral cortex and cerebellum were indistinguishable. However, several appeared to be uniquely human when compared with the products synthesized by mouse brain mRNA. The method described for the preparation of postmortem human brain mRNA eliminates the need to prepare polysomes, which are recovered in variable and low yield from the postmortem human brain. The procedure appears applicable to studies on the synthesis of moderately large human brain polypeptides and for investigations of brain protein polymorphism when relatively large numbers of products are required for analysis.     

Protein Turnover in Brain of the Rat Fetus

Protein synthesis in vivo was studied in whole brain of rat fetuses using continuous intravenous infusion of L-[U-14C]tyrosine into unrestrained pregnant rats at 19 and 21 days gestation. Protein degradation (KD) was calculated by subtracting fractional growth rate of brain protein (KG) from the fractional synthesis rate (KS). KS was high at both gestational ages (0.42 +/- 0.03 days-1 at day 19, 0.47 +/- 0.029 days-1 at 21 days), comparable to values previously reported for newborn rat cerebral hemispheres, and threefold higher than is seen in adult animals. KD was similar at both 19 and 21 days gestation (0.19-0.24) and lower than that reported in neonatal rat brain using similar techniques. Protein accretion during the most rapid phase of brain growth (fetus) is accomplished by similar rates of protein synthesis, but decreased rates of degradation when compared with a slower growth phase (newborn). KD in the brain of the rapidly growing fetus is slightly higher than in adult cerebral hemispheres.     

Changes in Protein Content of Goldfish Optic Nerve During Degeneration and Regeneration Following Nerve Crush

Abstract: After the goldfish optic nerve was crushed, the total amount of protein in the nerve decreased by about 45% within 1 week as the axons degenerated, began to recover between 2 and 5 weeks as axonal regeneration occurred, and had returned to nearly normal by 12 weeks. Corresponding changes in the relative amounts of some individual proteins were investigated by separating the proteins by two-dimensional gel electrophoresis and performing a quantitative analysis of the Coomassie Brilliant Blue staining patterns of the gels. In addition, labelling patterns showing incorporation of [³H]proline into individual proteins were examined to differentiate between locally synthesized proteins (presumably produced mainly by the glial cells) and axonal proteins carried by fast or slow axonal transport. Some prominent nerve proteins, ON1 and ON2 (50–55 kD, pI ～6), decreased to almost undetectable levels and then reappeared with a time course corresponding to the changes in total protein content of the nerve. Similar changes were seen in a protein we have designated NF (～130 kD, pI ～5.2). These three proteins, which were labelled in association with slow axonal transport, may be neurofilament constituents. Large decreases following optic nerve crush were also seen in the relative amounts of α- and β-tubulin, which suggests that they are localized mainly in the optic axons rather than the glial cells. Another group of proteins, W2, W3, and W4 (35–45 kD, pI 6.5–7.0), which showed a somewhat slower time course of disappearance and were intensely labelled in the local synthesis pattern, may be associated with myelin. A small number of proteins increased in relative amount following nerve crush. These included some, P1 and P2 (35–40 kD, pIs 6.1–6.2) and NT (～50 kD, pI ～5.5), that appeared to be synthesized by the glial cells. Increases were also seen in one axonal protein, B (～45 kD, pI ～4.5), that is carried by fast axonal transport, as well as in two axonal proteins, HA1 and HA2 (～60 and 65 kD respectively, pIs 4.5–5.0), that are carried mainly by slow axonal transport. Other proteins, including actin, that showed no net changes in relative amount (but presumably changed in absolute amount in direct proportion to the changes in total protein content of the nerve), are apparently distributed in both the neuronal and nonneuronal compartments of the nerve.     

Topographical Distribution of Base Exchange Activities in Rat Brain Subcellular Fractions

Abstract: Enrichment in the base-exchange activities was found in the micro-somal fraction of rat brain, with less activity being associated with nuclei, mitochondria and synaptosomes. The distribution of the choline base exchange in microsomal subfractions differed from that for serine and ethanolamine and these three activities seemed asymmetrically distributed in the microsomes. Choline exchange activity was trypsin-sensitive and presumably was located on the cytoplasmic side of the microsomes, while serine and ethanolamine exchange activities were trypsin-insensitive and were assumed to be located on the luminal side of the microsomes. Treatment of rat brain microsomes with phospholipases A, C and D produced significant losses of membrane-bound base exchange activities. Some activity was restored in phospholipase C-treated microsomes by exogenous phospholipid, but significant restoration was not observed in phospholipase A-treated microsomes by such additions. Exogenous phospholipid stimulated choline and ethanolamine exchange activities, but not serine exchange activity of phospholipase D-treated microsomes. The exchange activities of rat brain microsomes differed in their responses to treatment with phospholipases, choline exchange activity in general being more sensitive than either serine or ethanolamine activities.     

Regional and Subcellular Distribution of Thy-1 in Human Brain Assayed by a Solid-Phase Radioimmunoassay

A solid-phase radioimmunoassay, specific for the monomeric form of human Thy-1, was developed and used for quantitation of the Thy-1 antigen in human brain tissue. Determination of Thy-1 in homogenates of 12 anatomically defined brain regions showed that Thy-1 is present throughout the human brain. However, significant variation was found in the expression of the glycoprotein in different regions. Thy-1 appears to be generally enriched within gray matter: caudate nucleus, cerebral cortex, and putamen were found to contain the highest Thy-1 concentration (approximately 2.5 micrograms Thy-1/mg protein). Interestingly, the cerebellar cortex contained only 25% of the Thy-1 concentration of cerebral gray matter. Cerebral subcortical white matter contained half the amount of Thy-1 compared to cerebral cortex. Determination of Thy-1 in subcellular fractions prepared from human brain biopsy tissue indicated that the highest relative concentration of Thy-1 is associated with synaptosomal membranes and myelin/axonal membrane fractions.     

Effect of Hypothyroidism on the Subcellular Distribution of Ca2+/Calmodulin-Stimulated Protein Kinase II in Chicken Brain During Posthatch Development

Abstract: In developing chicken brain Ca²⁺/calmodulin-stimulated protein kinase II (CaMPK-II) changes from being primarily cytosolic to being primarily particulate during the protracted maturation period. To investigate whether thyroid hormone levels may be involved in regulating this subcellular redistribution, we raised chickens from 1 day posthatching on food soaked in 0.15% (wt/vol) propylthiouracil (PTU) plus 0.05% (wt/vol) methimazole (MMI). This produced a mild hypothyroidism specifically during the maturation period and resulted in a 67% reduction in the levels of free triiodothyronine (T₃) at 42 days. The concentrations of α- and β-CaMPK-II in cytosol (S3) and crude synaptic membrane (P2M) fractions from forebrain were measured by three methods: Ca²⁺/calmodulin- or Zn²⁺-stimulated autophosphorylation or binding of biotinylated calmodulin. By all three methods hypothyroid animals showed a marked retardation of the redistribution of both subunits of CaMPK-II: an increase in the concentration of the enzyme in S3 and a corresponding decrease in P2M with no overall change in the total amount of enzyme and little apparent change in the concentration of other proteins. In both fractions, there was a parallel change in the Ca²⁺/calmodulin-stimulated phosphorylation of endogenous protein substrates but no change in the basal or cyclic AMP-stimulated protein phosphorylation. Supplementing the PTU/MMI-treated diet with thyroxine (0.5 ppm) prevented all of the observed changes.     

Subcellular Distribution of Prolyl Endopeptidase and Cation-Sensitive Neutral Endopeptidase in Rabbit Brain

Abstract: The subcellular distribution of prolyl endopeptidase, and of cationsensitive neutral endopeptidase, two enzymes actively metabolizing many neuropeptides, was determined in homogenates of rabbit brain. The subcellular distribution of both enzymes was more similar to lactate dehydrogenase, a cytoplasmic enzyme marker, than to choline acetyltransferase, a synaptosomal marker. Only 35% of the activity of these two neutral endopeptidases was found in the crude mitochondrial fraction (P₂), the bulk of the remaining activity being associated with the high-speed supernatant. Prolyl endopeptidase and cation-sensitive neutral endopeptidase thus can be regarded as mainly cytoplasmic enzymes in the rabbit brain.     

Rapid adaptation: a new dimension for evolutionary perspectives in ecology

Although the study of adaptation is central to biology, two types of adaptation are recognized in the biological field: physiological adaptation (accommodation or acclimation; an individual organism’s phenotype is adjusted to its environment) and evolutionary–biological adaptation (adaptation is shaped by natural selection acting on genetic variation). The history of the former concept dates to the late nineteenth and early twentieth centuries, and has more recently been systemized in the twenty-first century. Approaches to the understanding of phenotypic plasticity and learning behavior have only recently been developed, based on cellular–histological and behavioral–neurobiological techniques as well as traditional molecular biology. New developments of the former concepts in phenotypic plasticity are discussed in bacterial persistence, wing di-/polymorphism with transgenerational effects, polyphenism in social insects, and defense traits for predator avoidance, including molecular biology analyses. We also discuss new studies on the concept of genetic accommodation resulting in evolution of phenotypic plasticity through a transgenerational change in the reaction norm based on a threshold model. Learning behavior can also be understood as physiological phenotypic plasticity, associating with the brain–nervous system, and it drives the accelerated evolutionary change in behavioral response (the Baldwin effect) with memory stock. Furthermore, choice behaviors are widely seen in decision-making of animal foragers. Incorporating flexible phenotypic plasticity and learning behavior into modeling can drastically change dynamical behavior of the system. Unification of biological sciences will be facilitated and integrated, such as behavioral ecology and behavioral neurobiology in the area of learning, and evolutionary ecology and molecular developmental biology in the theme of phenotypic plasticity.     

硒、谷胱甘肽过氧化物酶和不饱和脂肪酸在鼠脑亚细胞中的分布

采用梯度离心和放射性同位素等方法从鼠脑中分离得到髓磷脂、突触囊、轻突触体、重突触体、线粒体６个亚细胞组分。分别测定了各亚细胞中硒－７５、谷胱甘肽过氧化物酶和不饱和脂肪酸的含量,结果表明这些成分在鼠脑亚细胞中的分布呈现明显的相关性,同时首次在突触囊、线粒体和微粒体中检测到三种不同的谷胱甘肽过氧化物酶的活性峰,其中之一可能是红细胞谷胱甘肽过氧化物酶（ＥＣ１．１１．１．９）．还就机体的自我保护机制和硒在脑组织中的重要作用进行了讨论。     

Distribution of Six Synaptic Membrane Antigens in Subcellular Fractions of Rat Brain Cortex

Abstract: The subcellular distribution in rat brain cortex of six synaptic membrane antigens (56K, 58K, 62K, 63K, 64K, 66K) was studied by rocket immunoelectrophoresis, using antiserum to a highly purified synaptic plasma membrane fraction. Initial analysis of the insoluble portion of subcellular fractions showed that these antigens were also present in smooth microsomes, rough microsomes, and synaptic vesicles; that only traces were present in synaptic junctions; and that none was present in nuclei, mitochondria, and myelin. A trace amount of activity was also present in synaptic vesicle cytosol, but none in whole brain cytosol. Quantitative measurements of synaptic plasma membranes, smooth microsomes, and synaptic vesicles showed that all six antigens were present in synaptic plasma membranes and smooth microsomes, but that the 66K antigen was absent from synaptic vesicles. The 56K, 58K, 62K, 63K, and 64K antigens were present in highest concentration in synaptic plasma membranes, whereas the 66K antigen content was highest in smooth microsomes. Only the 58K, 62K, and 63K antigens were detectable in the membrane fraction of whole brain. Their enrichments in synaptic plasma membranes were 10.9, 5.4, and 5.9, respectively. We conclude that the 56K, 58K, 62K, 63K and 64K antigens are primary components of synaptic plasma membranes. The presence of synaptic plasma membrane antigens in smooth microsomes and synaptic vesicles probably represents material being actively transported, consistent with the hypothesis that proteins of synaptic plasma membranes and synaptic vesicles are transported via smooth endoplasmic reticulum.     

Hyperthermia Induces the Synthesis of a Heat Shock Protein by Polysomes Isolated from the Fetal and Neonatal Mammalian Brain

Abstract: Analysis of the cell-free translation products of polysomes isolated from fetal brain and other organs indicates that elevation of maternal body temperature induces the synthesis of a heat shock protein of molecular weight 74,000 (74K). The newborn mammal is particularly sensitive to induction of the 74K protein. As early postnatal development proceeds, higher body temperatures are required to induce synthesis of the 74K heat shock protein.     

Effect of Intravenous Administration of d-Lysergic Acid Diethylamide on Subsequent Protein Synthesis in a Cell-Free System Derived from Brain

Abstract: An initiating cell-free protein synthesis system derived from brain was utilized to demonstrate that the intravenous injection of d -lysergic acid diethylamide (LSD) to rabbits induced a transient inhibition of translation following a brief stimulatory period. Subfractionation of the brain cell-free system into postribosomal supernatant (PRS) and microsome fractions demonstrated that LSD in vivo induced alterations in both of these fractions. In addition to the overall inhibition of translation in the cell-free system, differential effects were noted, i.e., greater than average relative decreases in in vitro labeling of certain brain proteins and relative increases in others. The brain proteins of molecular weights 7SK and 95K, which were increased in relative labeling under conditions of LSD-induced hyperthermia, are similar in molecular weight to two of the major "heat shock" proteins reported in tissue culture systems. Injection of LSD to rabbits at 4°C prevented LSD-induced hyperthermia but behavioral effects of the drug were still apparent. The overall decrease in cell-free translation was still observed but the differential labeling effects were not. LSD appeared to influence cell-free translation in the brain at two dissociable levels: (a) an overall decrease in translation that was observed even in the absence of LSD-induced hyperthermia and (b) differential labeling effects on particular proteins that were dependent on LSD-induced hyperthermia.     

Regional and Subcellular Distribution of ATP-Citrate Lyase and Other Enzymes of Acetyl-CoA Metabolism in Rat Brain

The activities of ATP-citrate lyase in frog, guinea pig, mouse, rat, and human brain vary from 18 to 30 μmol/h/g of tissue, being several times higher than choline acetyltransferase activity. Activities of pyruvate dehydrogenase and acetyl coenzyme A synthetase in rat brain are 206 and 18.4 μmol/h/g of tissue, respectively. Over 70% of the activities of both choline acetyltransferase and ATP-citrate lyase in secondary fractions are found in synaptosomes. Their preferential localization in synaptosomes and synaptoplasm is supported by RSA values above 2. Acetyl CoA synthetase activity is located mainly in whole brain mitochondria (RSA, 2.33) and its activity in synaptoplasm is low (RSA, 0.25). The activities of pyruvate dehydrogenase, citrate synthase, and carnitine acetyltransferase are present mainly in fractions C and B_p. No pyruvate dehydrogenase activity is found in synaptoplasm. Striatum, cerebral cortex, and cerebellum contain similar activities of pyruvate dehydrogenase, citrate synthase, carnitine acetyltransferase, fatty acid synthetase, and acetyl-CoA hydrolase. Activities of acetyl CoA synthetase, choline acetyltransferase and ATP-citrate lyase in cerebellum are about 10 and 4 times lower, respectively, than in other parts of the brain. These data indicate preferential localization of ATP-citrate lyase in cholinergic nerve endings, and indicate that this enzyme is not a rate limiting step in the synthesis of the acetyl moiety of ACh in brain.