Colchicine-binding activity in particulate fractions of mouse brain

Both particulate and soluble fractions of brain homogenates bound [³H]colchicine. Approximately one-half of the total colchicine-binding activity in mouse brain was found in the particulate fraction. Of the particulate fractions, the microsomal and nerveending subfractions which sediment at the 1·0–1·2 m interface on sucrose gradients were richest in colchicine-binding activity. Intact microtubules were not found in these fractions, but colchicine-binding activity of these fractions may be related to the presence of microtubular protein.     

Ribonuclease activities in rat sympathetic ganglia: Evidence for the presence of an endogenous inhibitor of alkaline ribonuclease

Using³H-labeled rat brain mature RNA as substrate, substantial ribonuclease activity was detected in homogenates of rat superior cervical ganglia with acidic (pH 5.5) and neutral (pH 7.0-7.5) optima. Very little activity could be measured at greater than pH 8. The acidic and neutral activities differed in the optimal conditions required for assay, and showed differential sensitivity to the sulfhydryl blocking agent, N-ethylmaleimide. Only the neutral activity was stimulated, optimally by 2 mM N-ethylmaleimide, and the magnitude of stimulation indicated that the contributing ribonucleases exist largely in a latent form in the ganglion. Ribonucleases in other tissues with neutral pH dependence, known usually as alkaline ribonucleases, are subject to an N-ethylmaleimide-sensitive endogenous inhibitor protein. The existence of a similar inhibitor in rat superior cervical ganglia was indicated by the latency of neutral ribonuclease activity and confirmed by observing the effect of a soluble fraction from the ganglia on the activity of pancreatic ribonuclease A.     

BIOCHEMICAL AND IMMUNOLOGICAL CHARACTERIZATION OF ALKALOID-BINDING PROTEINS FROM IMMATURE RAT BRAIN1

Abstract— Vinblastine- and colchicine-binding proteins in the soluble fraction of immature rat brains were characterized and compared. Based upon criteria of Sephadex G-200 chromatography, electrofocusing and immunological reactivity, several separable species of vinblastine-binding protein were isolated. By contrast, these same procedures yielded only one protein band or elution peak to which [¹⁴C]colchicine could be tightly bound. This colchicine-binding protein peak coincided, in part, with one of the protein peaks to which [³H]vinblastine was tightly bound. Rabbit antiserum against soluble brain proteins precipitated by vinblastine sulfate contained antibodies which reacted with colchicine-binding protein. Thus, despite apparent differences in physical properties between the bulk of the vinblastine-binding proteins and the colchicine-binding protein, the vinblastine sulfate-precipitated protein antigens gave rise to antibodies capable of forming an immune complex with colchicine-binding protein.     

CHOLINE ACETYLTRANSFERASE, ACETYLCHOLINESTERASE AND AROMATIC l-AMINO ACID DECARBOXYLASE IN SINGLE IDENTIFIED NERVE CELL BODIES FROM SNAIL HELIX ASPERSA

—The distribution of choline acetyltransferase, aromatic l -amino acid decarboxylase and acetylcholinesterase in the nervous system of Helix aspersa has been studied using homogenates of whole ganglia, microdissection from freeze-dried sections and dissection of single neurons from fresh tissue. Choline acetyltransferase was found in both the cell body and neuropil layers of all the Helix ganglia. The enzyme was not specifically localized to any ganglion or region of ganglion. Between 10 and 30 per cent of the isolated single cell bodies contained the enzyme. The enzymic activity corresponded to 50–200 mmol ACh/1 cell bodies/h. Choline acetyltransferase is probably a specific marker for cholinergic cells in this species. Aromatic l -amino acid decarboxylase was more selectivity localized and its distribution corresponded well with that of monoamine containing cells as visualized by the fluorescence histochemical technique. A large proportion of cell bodies were localized in the boundary between the visceral and right parietal ganglia and in the pedal ganglion. The other ganglia contained few such cells. The activity of aromatic l -amino acid decarboxylase corresponded 10–50 mmol dopamine/1 cell bodies/h. A method was developed to measure the enzyme activity towards 5-hydroxytryptophan and DOPA in single cells simultaneously. The ratio between the activity towards both substrates did not vary significantly for the different cells. The enzyme is probably a specific marker for monoamine cells, but cannot be used to differentiate between the different monoamine cells. Acetylcholinesterase was uniformly distributed in the ganglia and was probably present in all nerve cells.     

Release of dopamine and serotonin from Limax ganglia in vitro

1. We wish to establish the kinetics of serotonin and dopamine release from Limax cerebral and buccal ganglia and find selective treatments to modify their release kinetics.2. The release of dopamine and serotonin from isolated ganglia was stimulated by high potassium exposure with and without prior treatment of ganglia with 6-hydroxydopamine (6-OHDA).3. Single ganglia release significant quantities of monoamines during a single 5 min high K⁺ exposure. Multiple high K⁺ exposures deplete a readily releasable transmitter store with little effect on storage pools.4. 6-OHDA exposure depletes readily releasable DA with little effect on total ganglion DA content or on serotonin.5. Feeding motor program responsiveness is suppressed reversibly by whole ganglion high K⁺ treatment.     

SYNTHESIS AND STORAGE OF MICROTUBULE PROTEINS BY SEA URCHIN EMBRYOS

Studies employing colchicine binding, precipitation with vinblastine sulfate, and acrylamide gel electrophoresis confirm earlier proposals that Arbacia punctulata and Lytechinus pictus eggs and embryos contain a store of microtubule proteins. Treatment of 150,000 g supernatants from sea urchin homogenates with vinblastine sulfate precipitates about 5% of the total soluble protein, and 75% of the colchicine-binding activity. Electrophoretic examination of the precipitate reveals two very prominent bands. These have migration rates identical to those of the A and B microtubule proteins of cilia. These proteins can be made radioactive at the 16 cell stage and at hatching by pulse labeling with tritiated amino acids. By labeling for 1 hr with leucine-³H in early cleavage, then culturing embryos in the presence of unlabeled leucine, removal of newly synthesized microtubule proteins from the soluble pool can be demonstrated. Incorporation of labeled amino acids into microtubule proteins is not affected by culturing embryos continuously in 20 µg/ml of actinomycin D. Microtubule proteins appear, therefore, to be synthesized on "maternal" messenger RNA. This provides the first protein encoded by stored or "masked" mRNA in sea urchin embryos to be identified.     

Microtubule assembly in developing mammalian brain.

Microtubule protein was measured in mouse brain homogenates by quantitative colchicine binding. Neonatal animals contained more than twice the amount of brain tubulin as adult mice. The percentage of colchicine-binding protein which was polymerized was determined by extracting brain at room temperature into a medium designed to stabilize intact microtubules. Under identical conditions and tubulin concentrations, neonatal brain tubulin (colchicine-binding activity) had a greater proportion of the total extracted in an apparently polymerized state (pelletable by centrifugation) than did adult brain. A slight variation in the ratio of assembled to unassembled tubulin was observed with varying protein concentration (volume of extract), indicating that the values obtained may not reflect exactly the in vivo situation, because a rapid equilibration takes place upon homogenization. At all protein concentrations, the neonatal brain extracts contained a significantly greater proportion of assembled tubulin than did adult brain. This proportion began to fall at 5 days postnatal and reached the adult level at 30 days. The tubulin assembled/not assembled ratios were not altered by addition of nucleoside triphosphates, additional EGTA, or sulfhydryl protecting agents, and did not vary with preparation times of 30–90 min. The colchicine-binding reaction and decay of colchicine-binding activity with time were similar in extracts of different aged mouse brains, with neonatal slightly more stable than adult. Pools of tubulin from any age which were soluble at room temperature (unpolymerized) could not repolymerize well in vitro when incubated with GTP at 37 °C, whereas pools of tubulin which were sedimentable at room temperature (polymerized) could be redissolved at 0 °C and readily reassembled at 37 °C. The neonatal extract tubulin was thus more polymerization competent than the adult extracts; this correlates with a greater proportion of assembled tubulin in extracts at room temperature and possibly in vivo.     

Biosynthesis of prostaglandin E by rat superior cervical ganglia.

Abstract— —The biosynthesis of immunoreactive prostaglandin E (iPGE) was examined in homogenates of rat superior cervical ganglia and in isolated intact ganglia incubated in vitro. Ganglia homogenates produced iPGE from exogenous arachidonic acid. Prostaglandin synthesis by the homogenates was inhibited by the prostaglandin synthetase inhibitors, eicosatetraynoic acid, indomethacin and sodium meclofenamate and was stimulated by norepinephrine and dopamine. Whole ganglia incubated in Krebs-bicarbonate solution also synthesized iPGE which was released into the incubation bath in a time-dependent manner. As observed in the homogenates, norepinephrine and dopamine enhanced iPGE formation by the intact tissue. Phospholipase A also stimulated iPGE synthesis by the whole ganglia. The effect of phospholipase A was antagonized by dibutyryl cyclic AMP but not by dibutyryl cyclic GMP. The results suggest that neuronally synthesized prostaglandins may be available for modulating adrenergic neuron function and that endogenous neuronal constituents such as catecholamines and cyclic AMP may influence the activity of the prostaglandin synthetase system.     

Acetyl- and pseudocholinesterase activities in sympathetic ganglia of rats

—The quantitative method of Ellman , Courtney , Andres and Featherstone (1961) was adapted to a differential assay for the determination of acetyl- and pseudocholinesterase activities of sympathetic ganglia of rats. The activities of the cholinesterases of superior cervical, stellate and thoracic chain ganglia and of the abdominal ganglionic complexes in apposition to the superior mesenteric and coeliac arteries (superior mesenteric, coeliac and cardiac ganglia) were measured. B.W.284C51 dibromide, 5 × 10^?5m , and ethopropazine hydrochloride, 3·15 × 10^?5m , were employed to inhibit selectively acetyl- and pseudocholinesterases, respectively. Linearity was shown to be maintained with enzyme concentrations corresponding to 0·12-0·5 mg of ganglion (wet wt.)/incubation. Under the experimental conditions of this assay, the rates of the reaction of ganglionic acetyl- and pseudocholinesterases were linear for time periods greater than those employed for calculating the rates of hydrolysis in the homogenates of sympathetic ganglia. Several experimental approaches were used to ascertain the specificity of the inhibitors and of the reaction. Of the total cholinesterase activity of sympathetic ganglia of rats, 55-63 per cent was due to acetylcholinesterase and 31-39 per cent to pseudocholinesterase. On the basis of the specific enzyme activity, superior cervical, stellate and superior mesenteric ganglia contained higher acetyl- and pseudocholinesterase activities than did thoracic chain, coeliac and cardiac (abdominal) ganglia. The specific activity of acetylcholinesterase was similar in rat and cat superior cervical ganglia and sympathetic cervical trunks while the pseudocholinesterase activity of these two tissues was somewhat lower in cats than in rats.     

Isolation of pigmented granules involved in extra-retinal photoreception in Aplysia californica neurons

Many neurons in the ganglia of Aplysia california contain pigmented, membrane-bound granules (lipochondria), which are thought to mediate the light response of some of the neurons, including the giant cell of the abdominal ganglion. A method of isolating the lipochondria by centrifugation of ganglia homogenates has now been developed. Electron microscopy was used to demonstrate that most of the lipochondria remain morphologically intact. As shown by X-ray microanalysis, isolated lipochondria contain the same elements, including calcium, as do lipochondria in intact giant cells. The calcium can be released into the medium by treatment of the organelles with the Ca²⁺ ionophore A23187. It appears that the lipochondria of Aplysia ganglia are similar in their morphology, elemental content and susceptibility to the ionophore. Two pigments were isolated from the lipochondria, and chromatography and spectrophotometric studies indicated that they are β-carotene and a “retinol-like” compound.     

The source and action of head factors regulating juvenile hormone esterase in larvae of the cabbage looper, Trichoplusia ni

Brain (median or lateral regions) or suboesophageal ganglion (SOG) homogenates of Day 1 fifth instar larvae of Trichoplusia ni induced the appearance of haemolymph juvenile hormone esterase (JHE) when injected into Day 1, Day 2 or early Day 4 fifth instar ligated hosts. Brain and SOG homogenates of late fourth instars also induced JHE when injected into Day 1 hosts, whole late fifth instar and pupal tissue did not. The pattern of JHE induction by early fourth through Day 3 fifth instar brain and SOG homogenates correlated with natural haemolymph JHE activity occurring at these times. Implantation of late fourth and Day 1 fifth instar brains and/or SOG into similar age hosts similarly induced JHE activity while prothoracic and abdominal ganglia did not. The relative levels of induction following implantation were SOG<brain<brain+SOG. JHE activity which appears in the haemolymph following injection of brain homogenates appears to be largely due to a single enzyme which has an isoelectric point indistinguishable from that of the natural haemolymph enzyme. Evidence is presented which suggests that inhibitory as well as stimulatory brain factors are involved in JHE regulation.     

THE CELL-FREE SYNTHESIS OF ALKALOID-BINDING PROTEINS IN IMMATURE RAT BRAIN1

Abstract— cell-free amino acid incorporating system from immature rat brain, consisting of ribosomal and soluble fractions, has been investigated for its capacity to incorporate [¹⁴C]amino acids into specific soluble proteins that interact with vinblastine sulfate and colchicine. The soluble ¹⁴C-labeled proteins formed in the cell-free system during incubation were compared with similar soluble proteins from immature rat brain which had been labeled in vivo by the incorporation of ¹⁴C-labeled amino acids. Criteria for the formation of vinblastine-binding, ¹⁴C-labeled proteins were: (1) aggregation of ¹⁴C-labeled soluble protein by one mm -vinblastine sulfate and (2) immunoprecipitation of ¹⁴C-labeled soluble protein by an antiserum against vinblastine sulfate-precipitable material. Criteria for the formation of [³H]colchicine-binding, ¹⁴C-labeled protein were based upon: (1) co-precipitation of the ³H-and ¹⁴C-labeled materials by vinblastine sulfate and (2) the coincidence of ³H- and ¹⁴C-labeled elution peaks from columns of Sephadex G-200, DEAE-Sephadex A-50 and isoelectric focusing. Both in the in vitro and in the in vivo system, ¹⁴C-labeled amino acids were incorporated into soluble proteins of the post-microsomal supernatant fraction. Proteins labeled with ¹⁴C-labeled amino acids in vitro and in vivo yielded comparable and qualitatively identical results by the criteria tested, including the formation of immunoprecipitates. In the in vitro system, ¹⁴C-labeled amino acids were incorporated into protein with a molecular weight of approx 120,000, an isoelectric point of 5.3 and with a chromatographic mobility on Sephadex G-200 which is identical to [³H]colchicine-binding protein. The above experimental results are presumptive evidence for the synthesis of vinblastine-binding and colchicine-binding proteins in the in vitro cell-free system.     

Time course of appearance ofα-bungarotoxin binding sites during development of chick ciliary ganglion and iris

The binding of [¹²⁵I]alpha-bungarotoxin (ABTX) to homogenates of ciliary ganglia and irises from embryonic and posthatching chickens has been examined. Specific, high-affinity binding was found in both tissues [K _D (iris)=2.5 nM;K _D (ganglion)=2.7 nM]. Binding is saturated above 10 nM toxin concentration and is inhibited by low concentrations of the nicotinic antagonistd-tubocurarine. The binding may be associated with a nicotinic cholinergic receptor in both tissues. The amount of binding in the iris begins to increase soon after functional innervation is first observed, at 12 days of incubation (d.i.), and continues to increase up to four months after hatching (a.h.), the oldest age tested. In contrast, ABTX binding in the ciliary ganglion increases fourfold between 7 and 11 d.i., after which the amount of binding remains unchanged up to four months a.h. When compared to the development of choline acetyltransferase (ChAc) and acetylcholinesterase (AChE) activities in the ganglion and iris, ABTX binding follows a pattern similar to that of AChE activity. The largest increases in ChAc activity occur later than those of the postsynaptic markers. After 16 d.i. there are approximately 3×10⁶ toxin molecules bound per neuron in the ciliary ganglion.Submitted by V. A. Chiappinelli in partial fulfillment of the requirements for the PhD degree in the Department of Biobehavioral Sciences, University of Connecticut, Storrs, Connecticut.     

MICROTUBULE PROTEIN DURING CILIOGENESIS IN THE MOUSE OVIDUCT

A colchicine-binding assay and quantitative sodium dodecyl sulfate gel electrophoresis have been used to determine the changes which occur in microtubule protein (tubulin) concentrations in the particulate and soluble fractions of mouse oviduct homogenates during that period of development when centriole formation and cilium formation are at a maximum. When mouse oviducts, at various ages after birth, are homogenized in Tris-sucrose buffer, tubulin concentration is partitioned between the soluble (70%) and particulate (30%) fractions. During the period of most active organelle formation (3–12 days), there is a marked increase in colchicine-binding specific activity, in both the soluble and particulate fractions. Microtubule protein concentration increases from 16 to 24% in the soluble fraction, declining to 14% in the adult. In the particulate fractions, microtubule protein concentration increases from 16 to 27%, leveling off at 16% in the adult. We have concluded from these observations and from electron microscopy that colchicine-binding activity in the particulate fractions is related to the presence of centriole precursors in the pellets of homogenized oviducts from newborn mice. These data further suggest that centriole precursor structures are conveniently packaged aggregates of microtubule protein actively synthesized between 3 and 5 days, and maintained at a maximum during the most active period of organelle assembly.     

Homarus Americanus Stomatogastric Nervous System Dissection

With the goal of understanding how nervous systems produce activity and respond to the environment, neuroscientists turn to model systems that exhibit the activity of interest and are accessible and amenable to experimental methods. The stomatogastric nervous system (STNS) of the American lobster (Homarus americanus; also know was the Atlantic or Maine lobster) has been established as a model system for studying rhythm generating networks and neuromodulation of networks. The STNS consists of 3 anterior ganglia (2 commissural ganglia and an oesophageal ganglion), containing modulatory neurons that project centrally to the stomatogastric ganglion (STG). The STG contains approximately 30 neurons that comprise two central pattern generating networks, the pyloric and gastric networks that underlie feeding behaviors in crustaceans^1,2. While it is possible to study this system in vivo³, the STNS continues to produce its rhythmic activity when isolated in vitro. Physical isolation of the STNS in a dish allows for easy access to the somata in the ganglia for intracellular electrophysiological recordings and to the nerves of the STNS for extracellular recordings. Isolating the STNS is a two-part process. The first part, dissecting the stomach from the animal, is described in an accompanying video article⁴. In this video article, fine dissection techniques are used to isolate the STNS from the stomach. This procedure results in a nervous system preparation that is available for electrophysiological recordings.     

A histochemical and electrophysiological study of the action of diazoxon on cholinesterase activity and nerve conduction in ganglia of the cockroach Periplaneta americana L

When sixth abdominal or metathoracic ganglia of the cockroach Periplaneta americana L. were irrigated continuously with diazoxon (O, O-diethyl O-(2-isopropyl-6-methyl-4-pyrimidinyl) phosphate) solution in situ, the log. of the time required to block conduction in certain nerve pathways in the ganglia was directly proportional to the log. of the concentration of diazoxon applied. Inhibition of cholinesterase began peripherally before function was affected, and had begun to affect the neuropile by the time that conduction was first blocked. Longer exposure to diazoxon disrupted nerve function even more, especially in the sixth abdominal ganglion, and inhibited more cholinesterase, but much longer exposure was needed to inhibit nearly all the cholinesterase. Irrigation with saline, begun when block first occurred, failed to restore completely either nerve function or cholinesterase activity. The cholinesterase activity of ganglia from cockroaches treated topically with an LD90 of diazoxon and examined at intervals after treatment decreased steadily to a level similar to that of ganglia treated directly with diazoxon until conduction was just blocked, but rarely became less, even in moribund insects. Nerve function in metathoracic ganglia became badly affected and remained so in all cockroaches that failed to recover, but sixth abdominal ganglia, though usually badly affected for a time, always recovered normal function, even in prostrate cockroaches. The condition of a poisoned insect, therefore, corresponded much more closely to the functional condition of the metathoracic ganglion than to that of the sixth abdominal ganglion. Applying the insecticide close to a ganglion advanced the time of onset of symptoms but affected the final outcome very little. It was calculated that the highest concentration of diazoxon in the haemo-lymph in contact with the nervous systems of cockroaches treated topically with LDgo's of diazoxon was about 10^-5M.     

Quantitative studies of superior cervical sympathetic ganglia in a variety of primates including man. II. Neuronal packing density

The volumes of a sample of primate superior cervical sympathetic ganglia were measured and related to body weight and to the number of ganglionic neurons. Estimates of volumes of the ganglia varied between 1.956 mm³ in squirrel monkey and 173.530 mm³ in a human specimen. Average cell densities for the ganglia ranged from 4,455 cells/mm³ in a human ganglion to 32,528 cells/mm³ in a squirrel monkey ganglion. Mean cell territories varied from 0.0000307 mm³ in a squirrel monkey ganglion to 0.0002245 mm³ in a human ganglion. Analysis of the data reveals striking trends of correlation between body size, volume of ganglia, and average cell territories. Since similar correlations have been described for other types of neuronal cell aggregates, it is suggested that for any given nucleus, ganglion or cortical area, the neuronal packing density varies as a function of body size.     

Phosphorylation of tyrosine hydroxylase in the superior cervical ganglion

We studied the phosphorylation of tyrosine hydroxylase in the superior cervical ganglion of the rat. Ganglia were preincubated with [³²P]P_i and were then incubated in non-radioactive medium containing a variety of agents that are known to activate tyrosine hydroxylase in this tissue. Tyrosine hydroxylase was isolated from homogenates of the ganglia by immunoprecipitation followed by polyacrylamide gel electrophoresis. ³²P-labelled tyrosine hydroxylase was visualized by radioautography, and the incorporation of ³²P into the enzyme was quantitated by densitometry of the autoradiograms. Veratridine produced a concentration-dependent increase in the incorporation of ³²P into tyrosine hydroxylase, with 50 μM veratridine producing a 5-fold increase in ³²P incorporation. The nicotinic agonist, dimethylphenylpiperazinium (100 μM), caused a 7-fold increase in the phosphorylation of tyrosine hydroxylase. The effect of dimethylphenylpiperazinium was maximal within 1 min and decreased upon continued exposure of the ganglia to this agent. The actions of dimethylphenylpiperazinium and of veratridine were dependent on extracellular Ca²⁺. Muscarine, 8-Br-cAMP, forskolin, vasoactive intestinal peptide, isoproterenol, deoxycholate and phospholipase C also stimulated the incorporation of ³²P into tyrosine hydroxylase. These data support the hypothesis that phosphorylation plays a role in activation of tyrosine hydroxylase produced by all of these agents.     

Detection, determination, and metabolism in vitro of gangliosides in mammalian sympathetic ganglia

Abstract— Sympathetic ganglia of the rat and cat were examined for the occurrence and distribution of gangliosides. Each rat superior cervical ganglion contained 0.3 nmol of ganglioside-sialic acid. Extracts of cat superior cervical and nodose ganglia were chromatographed on silica gel thin-layer plates. The resulting patterns suggested that similar distributions of multiple forms of gangliosides occur in these two tissues, with the fast-moving gangliosides predominating. The metabolic activity of gangliosides was also investigated in rat superior cervical ganglia in vitro. Evidence was obtained that ¹⁴C from [U-¹⁴C]glucose, [U-¹⁴C]pyruvate, and [U-¹⁴C]glucosamine was incorporated into the gangliosides.     

Neurotubule assembly at substoichiometric nucleotide levels using a GTP regenerating system

Tubulin derived from cold depolymerized bovine microtubules has been gel filtered to obtain a tubulin preparation with only 3% of the tubulin dimers containing exchangeable [³H]-guanine nucleotide. In the presence of acetyl-P and bacterial acetate kinase, this preparation polymerizes to form microtubules which are morphologically indistinguishable from microtubules formed in the presence of excess GTP. The extent of microtubule formation at substoichiometric nucleotide levels using the GTP regenerating system exceeds the extent of assembly obtained with excess GTP. It is concluded that the exchangeable guanine nucleotide site can be virtually unoccupied in intact neurotubules and this finding indicates that GDP can “catalyze” tubule assembly in the presence of a GTP regenerating system.