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.     

Genes encoding giant danio and golden shiner ependymin

Ependymin (EPN) is a brain glycoprotein that functions as a neurotrophic factor in optic nerve regeneration and long-term memory consolidation in goldfish. To date, trueepn genes have been characterized in one order of teleost fish,Cypriniformes. In the study presented here, polymerase chain reactions were used to analyze the completeepn genes,gd (1480 bp), andsh (2071 bp), fromCypriniformes giant danio and shiner, respectively. Southern hybridizations demonstrated the existence of one copy of each gene per corresponding haploid, genome. Each gene was found to contain six exons and five introns. Genegd encodes a predicted 218-amino acid (aa) protein GD 93% conserved to goldfish EPN, whilesh encodes a predicted 214-aa protein SH 91% homologous to goldfish. Evidence is presented classifying proteins previously termed “EPNs” into two major categories: true EPNs and non-EPN cerebrospinal fluid glycoproteins. Proteins GD and SH contain all the hallmark features of true EPNs.     

Extracellular fluid proteins of goldfish brain: Studies of concentration and labeling patterns

An extraction procedure for the isolation of proteins from the extracellular fluid (ECF) of goldfish brain was developed and applied in an investigation of the time course and pattern of labeling of ECF proteins. The results indicate that two out of the many protein bands present, which migrated at 32,000 and 26,000 daltons on SDS-polyacrylamide electrophoretic gels, could incorporate as much as 50% of the label of the ECF fraction, even though their concentration was only 14%. Measurements of the protein content of the ECF and its volume (24% of the brain) by the inulin method were used to calculate the protein concentration in the extracellular space of goldfish brain. This gave a value of 1.6–2%, i.e., about 50% of the value obtained for the protein concentration of the cytoplasmic fraction devoid of particulate matter. Such a result suggests that the goldfish brain intracellular and extracellular fluids, separated by the neural membranes, contain relatively comparable levels of proteins.     

The effect of gonadotropin-releasing hormone on growth hormone and gonadotropin subunit gene expression in the pituitary of goldfish, Carassius auratus

The goldfish brain contains at least two forms of gonadotropin-releasing hormone (GnRH): sGnRH and cGnRH-II. In goldfish sGnRH and cGnRH-II are present both in the brain and pituitary, and exert direct effects via specific GnRH receptors stimulating growth hormone (GH) and gonadotropin hormone (GtH) synthesis and secretion. In this study, we investigated the effects of sGnRH and cGnRH-II on GtH subunit (alpha, FSH-beta and LH-beta) and GH mRNA levels in the goldfish pituitary in vivo and in vitro. Injection of goldfish with sGnRH or cGnRH-II (4 microg/fish) stimulated GtH-alpha, FSH-beta and LH-beta mRNA levels after 24 h. For in vitro studies, goldfish pituitary fragments were treated continuously for 12 h with 10(-7) M sGnRH or cGnRH-II. Both sGnRH and cGnRH-II stimulated GtH-alpha, FSH-beta, LH-beta and GH mRNA levels, however, cGnRH-II appeared to have a more pronounced effect. Similar experiments were carried out using cultured dispersed goldfish pituitary cells. In this study, treatments for 12 h with 10(-7) M sGnRH or cGnRH-II also stimulated GtH and GH gene expression. The present results provide a basis for the investigation of the signal transduction pathways that mediate GnRH-induced changes in GtH subunit and GH mRNA levels in the goldfish pituitary.     

Adaptation of biological membranes to temperature. The effect of temperature acclimation of goldfish upon the viscosity of synaptosomal membranes

The fluidity of synaptosomal membrane preparations isolated from goldfish acclimated to 5, 15 and 25°C and from rat has been estimated using the fluorescence polarisation technique with 1,6-diphenyl-1,3,5-hexatriene as probe. Membranes of cold-acclimated goldfish were more fluid than those of warm-acclimated goldfish when measured at an intermediate temperature, indicating a temperature-dependent regulation of this parameter. Similarly, membranes of warm-acclimated goldfish were more fluid than those prepared from rat brain. Liposomes prepared from the purified phospholipids of goldfish and rat synaptosomal preparations showed differences similar to those of the native membranes. Increased membrane fluidity of cold-acclimated goldfish was correlated with a decrease in the proportion of saturated fatty acids of the major phospholipid classes and an increased unsaturation index in choline phosphoglycerides. Rat membranes showed a substantial reduction in unsaturation index and an increase in the proportion of saturated fatty acids compared to the membranes of 25°C-acclimated goldfish. The cholesterol content of synaptosomal membranes of goldfish was unaffected by acclimation treatment.The role of homeoviscous adaptation in the compensation of the rates of membrane processes during thermal acclimation, and upon the resistance adaptation of poikilotherms to extreme temperatures is discussed.     

Distribution and characterization of neuropeptide Y-like immunoreactivity in the brain and pituitary of the goldfish

Summary The distribution of neuropeptide Y (NPY) immunoreactivity has been studied by means of immunocytochemistry and radioimmunoassay in the brain of the goldfish. It was found that NPY had a widespread distribution in the entire brain in particular in the telencephalon, diencephalon, optic tectum and rhombencephalon. In the pituitary gland, positive type-B fibers were observed in the various lobes frequently in direct contact with secretory cells, in particular the gonadotrophs, somatotrophs and MSH (melanocyte-stimulating hormone) secreting cells. When measured by radioimmunoassay, the highest NPY concentrations were found in the pituitary and telencephalon, confirming the results of immunocytochemistry. The displacement curves obtained with serial dilutions of brain extracts were parallel to that of synthetic porcine NPY. Following high performance liquid chromatography, the NPY-like material extracted from goldfish brain co-eluted as a single peak with synthetic porcine NPY. These data demonstrate the presence of an NPY-like substance widely distributed in the goldfish brain. The observation of NPY-immunoreactive fibers in the pituitary gland suggests that, among its other functions, NPY may play a role in the neuroendocrine regulation of pituitary function.     

Feeding-induced changes of melanin-concentrating hormone (MCH)-like immunoreactivity in goldfish brain

Intracerebroventricular (ICV) injection of melanin-concentrating hormone (MCH) influences feeding behavior in the goldfish and exerts an anorexigenic action in goldfish brain, unlike its orexigenic action in mammals. Despite a growing body of knowledge concerning MCH function in mammals, the role of MCH in appetite has not yet been well studied in fish. The aim of the present study was to investigate the involvement of endogenous MCH in the feeding behavior of the goldfish. We examined the distribution of MCH-like immunoreactivity (MCH-LI) in the goldfish brain and the effect of feeding status upon this distribution. Neuronal cell bodies containing MCH-LI were localized specifically to four areas of the hypothalamus. Nerve fibers with MCH-LI were found mainly in the neurohypophysis, with a few in the telencephalon, mesencephalon, and diencephalon. The number of neuronal cell bodies containing MCH-LI in the dorsal area adjoining the lateral recess of the third ventricle in the posterior and inferior lobes of the hypothalamus showed a significant decrease in fasted fish compared with that in normally fed fish, although other areas showed no evident differences. We also administered an antiserum against fish MCH (anti-MCH serum) by ICV injection and examined its immunoneutralizing effect on food intake by using an automatic monitoring system. Cumulative food intake was significantly increased by ICV injection of the anti-MCH serum. These results indicate that MCH potentially functions as an anorexigenic neuropeptide in the goldfish brain, and that the further study of the evolutionary background of the MCH system and its role in appetite is warranted. This work was supported by Grants-in-Aid from the Ministry of Education, Culture, Sports, Science, and Technology of Japan (K.M. and A.T.) and by a research grant from the Toyama Marine Biotechnology Association (K.M.).     

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.     

Keratin 8 of simple epithelia is expressed in glia of the goldfish nervous system

The intermediate filament protein composition in glial cells of goldfish optic nerve differs from that found in glial cells of the goldfish spinal cord and brain. Brain and spinal cord glial cells contain glial fibrillary acidic protein (GFAP), whereas glial cells in the optic nerve contain ON3. The ON3 protein of the goldfish optic nerve was recently identified as the goldfish equivalent to the mammalian type II keratin 8 protein. In addition to the ON3 protein, the goldfish optic nerve also contains a 48-kDa protein. Immunoblotting experiments suggest that this protein is equivalent to the mammalian type I keratin 18 protein, which typically pairs with keratin 8 to form filaments. We show that these proteins are not specific to the optic nerve. The ON3 and 48-kDa proteins of the goldfish optic nerve share common antigenic properties with the predominant keratin pair expressed in the goldfish liver. These proteins are also expressed at low levels in the goldfish brain and spinal cord. In addition RNase protection assays and Northern blots indicate that the mRNA for the ON3 protein in optic nerve is identical to the message found in other goldfish tissues. The expression of ON3 was also examined in cultured glial cells from goldfish spinal cord and optic nerve and cultured fibroblast cells. Analysis of intermediate filament protein expression in cultured glial cells taken from goldfish spinal cord demonstrated the absence of GFAP in these cells and the expression of ON3. This protein was also the predominant intermediate filament protein of cultured optic nerve glial cells and fibroblasts. The differences in the expression of intermediate filament proteins in mammals and lower vertebrates are discussed. In addition, we discuss how the expression of a simple epithelial keratin pair in glial cells of the goldfish optic nerve may be associated with this system's capacity for continuous growth and regeneration.     

Immunoblot Identification of 13.5 Kilodalton Myelin Basic Protein in Goldfish Brain Myelin

Myelin isolated from goldfish brain shows a multilamellar structure with a major dense line and two intraperiod lines. Sodium dodecyl sulfate gel electrophoresis revealed that the protein profile of goldfish brain myelin is distinctly different from that of rat brain myelin. No protein migrating to the position of proteolipid protein or DM-20 was seen in goldfish myelin. Goldfish acclimated to 5 degrees, 15 degrees, and 30 degrees C showed no qualitative differences in myelin proteins. The 13.5 kD protein in goldfish brain myelin and brain homogenate was intensely immunostained with the antiserum to human basic protein by the immunoblot technique. In contrast, none of the proteins of goldfish myelin were immunostained with antiproteolipid protein serum; however, both proteolipid protein and DM-20 of rat brain myelin were immunostained. The significance of the synthesis of myelin proteins by astrocytes in the goldfish brain is discussed.     

Identification of keratins and analysis of their expression in carp and goldfish: comparison with the zebrafish and trout keratin catalog

With more than 50 genes in human, keratins make up a large gene family, but the evolutionary pressure leading to their diversity remains largely unclear. Nevertheless, this diversity offers a means to examine the evolutionary relationships among organisms that express keratins. Here, we report the analysis of keratins expressed in two cyprinid fishes, goldfish and carp, by two-dimensional polyacrylamide gel electrophoresis, complementary keratin blot binding assay, and immunoblotting. We further explore the expression of keratins by immunofluorescence microscopy. Comparison is made with the keratin expression and catalogs of zebrafish and rainbow trout. The keratins among these fishes exhibit a similar range of molecular weights and isoelectric points, with a similar overall pattern on two-dimensional gels. In addition, immunofluorescence microscopy studies of goldfish and carp tissues have revealed the expression of keratins in both epithelial and mesenchymally derived tissues, as reported previously for zebrafish and trout. We conclude that keratin expression is qualitatively similar among these fishes, with goldfish and carp patterns being more similar to each other than to zebrafish, and the cyprinid fishes being more similar to each other than to the salmonid trout. Because of the detected similarity of keratin expression among the cyprinid fishes, we propose that, for certain experiments, they are interchangeable. Although the zebrafish distinguishes itself as being a developmental and genetic/genomic model organism, we have found that the goldfish, in particular, is a more suitable model for both biochemical and histological studies of the cytoskeleton, especially since goldfish cytoskeletal preparations seem to be more resistant to degradation than those from carp or zebrafish. This work was supported by grants to J.M. from the Stiftung Rheinland Pfalz für Innovation (836-386261/138) and the Deutsche Forschungsgemeinschaft (Ma 843/5-1) and a grant to D.G. from the National Science Foundation (INT-0078261).     

Calcium and other signalling pathways in neuroendocrine regulation of somatotroph functions

Relative to mammals, the neuroendocrine control of pituitary growth hormone (GH) secretion and synthesis in teleost fish involves numerous stimulatory and inhibitory regulators, many of which are delivered to the somatotrophs via direct innervation. Among teleosts, how multifactorial regulation of somatotroph functions are mediated at the level of post-receptor signalling is best characterized in goldfish. Supplemented with recent findings, this review focuses on the known intracellular signal transduction mechanisms mediating the ligand- and function-specific actions in multifactorial control of GH release and synthesis, as well as basal GH secretion, in goldfish somatotrophs. These include membrane voltage-sensitive ion channels, Na(+)/H(+) antiport, Ca(2+) signalling, multiple pharmacologically distinct intracellular Ca(2+) stores, cAMP/PKA, PKC, nitric oxide, cGMP, MEK/ERK and PI3K. Signalling pathways mediating the major neuroendocrine regulators of mammalian somatotrophs, as well as those in other major teleost study model systems are also briefly highlighted. Interestingly, unlike mammals, spontaneous action potential firings are not observed in goldfish somatotrophs in culture. Furthermore, three goldfish brain somatostatin forms directly affect pituitary GH secretion via ligand-specific actions on membrane ion channels and intracellular Ca(2+) levels, as well as exert isoform-specific action on basal and stimulated GH mRNA expression, suggesting the importance of somatostatins other than somatostatin-14.     

The role of brain extracellular proteins in neuroplasticity and learning

Double labeling studies of the pattern of protein synthesis in goldfish and mouse brain identified a class of glycoproteins (the ependymins) whose turnover rate was enhanced after training. A variety of control experiments indicated that these macromolecules have an important role in the molecular and cell biology of learning. Antisera to the ependymins when injected into the brains of trained goldfish cause amnesia of a newly acquired behavior. Isolation and localization studies by immunocytochemical methods indicate that the ependymins are released into the brain extracellular fluid by a class of neurosecretory cells. In mammalian brain ependymin-containing cells are highly concentrated in the limibic system. The ependymins are constituted from two disulfide-linked acidic polypeptide chains (M.W.37K and 31K). They contain at least 5% covalently bound carbohydrate per chain with mannose, galactose, N-acetylglucosamine and N-acetylneuraminic acid as the predominant components. The highly soluble ependymins can rapidly polymerize to form an insoluble fibrous matrix if calcium is removed from solution by the addition of a Ca2+-chelating agent or dialysis. The self-aggregation property of the ependymins can be triggered by the depletion of Ca2+ from the extracellular space. Studies of the kinetics of the aggregation phenomenon by measurements of turbidity changes indicate that the process can be terminated but not reversed by restoring Ca2+ to its normal CSF level. Immunohistochemical studies of the brains of trained goldfish show the presence of punctate statining sites in the perimeter of certain cells located in specific brain regions. This suggests that ependymin aggregation might occur in vivo during learning. A molecular hypothesis relating the aggregation properties of the ependymins to neuroplasticity and learning is proposed.     

Species specificities of l-glutamic acid decarboxylase: Immunochemical comparisons

The relationship of catfish brain l-glutamic acid decarboxylase (GAD) with those from other species were examined by comparing the extent of their interactions with antibodies against catfish brain GAD. Several immunochemical methods, such as immunodiffusion, inhibition of enzyme activity and microcomplement fixation tests were employed for these studies. Antibodies against GAD from catfish brain were observed to cross-react with the enzymes from goldfish, frog, chick and turtle. Rabbit and bovine GAD did not cross-react with these antibodies. In the presence of the antibodies, enzymes from goldfish, frog. Drosophila, chick and crayfish were inhibited 27, 46, 32, 38 and 57% respectively. Enzymes from all the other species examined were not affected at all. Microcomplement fixation tests showed that goldfish, frog and chick GAD were quite similar in immunoreactivities. These immunochemical studies demonstrated that GAD from lower vertebrates such as chick, goldfish and frog and some invertebrates such as Drosophila and crayfish are closely related to catfish GAD. In contrast, mammalian GAD shows little or no cross-reactivity with antibodies against catfish GAD.     

Cloning of Multiple Forms of Goldfish Vimentin: Differential Expression in CNS

Abstract: In efforts to determine the primary structure of intermediate filament proteins in the goldfish visual pathway, we isolated clones from a retinal λgt11 cDNA expression library that represent goldfish vimentin. We show that there are at least two forms of goldfish vimentin, designated as vimentin α and vimentin β. RNase protection assays indicate that vimentin α mRNA is expressed in low amounts in retina, optic nerve, and brain and in higher amounts in spinal cord. In contrast, vimentin β mRNA is expressed in low amounts in retina, optic nerve, brain, and spinal cord and in very high amounts in eye lens. Immunohistochemical studies show that in the optic nerve, vimentin α is mainly restricted to blood vessels, meninges, and septa. Light staining is observed with this antibody in an astrocytic glial pattern throughout the optic nerve. Two-dimensional gel analysis shows that all of these goldfish vimentins are low abundant components of optic nerve cytoskeletal preparations.     

Neuronal interaction between melanin-concentrating hormone- and alpha-melanocyte-stimulating hormone-containing neurons in the goldfish hypothalamus

Intracerebroventricular (ICV) administration of melanin-concentrating hormone (MCH) inhibits food intake in goldfish, unlike in rodents, suggesting that its anorexigenic action is mediated by alpha-melanocyte-stimulating hormone (alpha-MSH) but not corticotropin-releasing hormone. This led us to investigate whether MCH-containing neurons in the goldfish brain have direct inputs to alpha-MSH-containing neurons, using a confocal laser scanning microscope, and to examine whether the anorexigenic action of MCH is also mediated by other anorexigenic neuropeptides, such as cholecystokinin (CCK) and pituitary adenylate cyclase-activating polypeptide (PACAP), using their receptor antagonists. MCH- and alpha-MSH-like immunoreactivities were distributed throughout the brain, especially in the diencephalon. MCH-containing nerve fibers or endings lay in close apposition to alpha-MSH-containing neurons in the hypothalamus in the posterior part of the nucleus lateralis tuberis (NLTp). The inhibitory effect of ICV-injected MCH on food intake was not affected by treatment with a CCK A/CCK B receptor antagonist, proglumide, or a PACAP receptor (PAC(1) receptor) antagonist, PACAP((6-38)). ICV administration of MCH at a dose sufficient to inhibit food consumption also did not influence expression of the mRNAs encoding CCK and PACAP. These results strongly suggest that MCH-containing neurons provide direct input to alpha-MSH-containing neurons in the NLTp of goldfish, and that MCH plays a crucial role in the regulation of feeding behavior as an anorexigenic neuropeptide via the alpha-MSH (melanocortin 4 receptor)-signaling pathway.     

Variable homeoviscous responses of different brain membranes of thermally-acclimated goldfish

The effects of thermal acclimation of goldfish upon the bulk fluidity of synaptic, mitochondrial and myelin membrane fractions of brain was determined using steady-state and differential polarised phase fluorimetry. Membrane fluidity decreased in the order, mitochondria>synaptic membranes>myelin. In each case membranes from cold-acclimated goldfish were more fluid than the corresponding membranes of warm-acclimated goldfish, though the adjustment of fluidity in each case was insufficient to compensate for the direct effects of the temperature difference. The extent of fluidity compensation was greatest in the mitochondrial fraction and least in the myelin fraction, indicating heterogeneous responses in different membrane-types. Steady-state and dynamic fluorimetric techniques provided identical estimates of the homeoviscous responses, indicating that despite its short-comings, the steady-state technique provided as good a measure of adaptive responses as the more complex and sophisticated technique.     

Preprotachykinin gene expression in goldfish brain: sexual, seasonal, and postprandial variations

Recently, we described the complete nucleotide sequence of gamma-preprotachykinin (gamma-PPT) mRNA and the deduced amino acid sequence of the precursor on the basis of molecular cloning and sequence analysis of cDNA from goldfish brain. In the present study, gamma-PPT gene expression in the brain of goldfish was examined using quantitative Northern blot analysis. The results showed that the gamma-PPT gene is highly but differentially expressed in the olfactory bulbs, hypothalamus, and posterior brain regions. There are sexual dimorphism and seasonal variations in gamma-PPT gene expression. In addition, the postprandial changes in gamma-PPT gene expression in the olfactory bulbs and hypothalamus suggest that tachykinin peptides are involved in regulation of feeding behavior in goldfish.