Alkaline extraction of cholecystokinin-immunoreactivity from rat brain

Alkaline aqueous extractants remove from rat brain 2 to 4 times the CCK-immunoreactivity that is removed by acidic or neutral aqueous extractants. The distribution among the various hormonal forms appears to be independent of the extractant: about $\text{1}\text{10}$ in the larger basic forms (CCK-33 and CCK-39); about $\text{1}\text{4}$ as the C-terminal dodecapeptide (CCK-12) and the remainder as the octapeptide (CCK-8). In contrast, alkaline and acidic aqueous solutions are equally efficient in extraction of enkephalin-immunoreactivity from the same tissues. We are presently unable to account for the very different efficiencies of the various extractants in removing CCK-immunoreactivity from brain.     

Molecular forms of cholecystokinin in plasma from normal and gastrectomized human subjects following a fat meal

The present study was undertaken to characterize molecular forms of cholecystokinin (CCK) in human fat-stimulated plasma by Sephadex G50 column chromatography followed by radioimmunoassays employing 3 different region-specific antibodies. CCK was extracted and concentrated from plasma of healthy subjects by adsorption to SEP-PAK C18 cartridges and from plasma of gastrectomized patients by addition of 96% ethanol. Antibody 1703 binds to carboxy-terminal CCK-peptides containing at least 14 amino acid residues, antibody T204 to sulfated carboxy-terminal CCK-peptides and antibody 5135 to carboxy-terminal forms of CCK and gastrin. Four molecular forms of CCK were consistently demonstrated; peak I eluted in the void volume and comprised 1.8-10.2% of CCK-immunoreactivity, peak II eluted between the void volume and the CCK-33/39 standard and comprised 9.8-21.6%, peak III eluted at the position of the CCK-33/39 standard and comprised 42.4-55.4%, and peak IV eluted between the CCK-33/39 and CCK-14 standards and comprised 25.4-40.1% of CCK immunoreactivity. Since these 4 molecular forms reacted to all 3 CCK-antibodies it is likely that they contain the sulfated tyrosyl and carboxy-terminal regions of CCK and, therefore, possess biological activity.     

CCK-8 inhibits feeding-specific neurons in Navanax, an opisthobranch mollusc

Cholecystokinin has been implicated as a satiety factor in mammals because it inhibits feeding through peripheral and central mechanisms. The cellular mechanisms of the central actions of CCK have been difficult to study because of the complex circuitry of the mammalian brain. Navanax is an opisthobranch mollusc with a defined neural network for feeding behavior in which the central effects of CCK can be studied at the cellular level. Here we report the localization of CCK-immunoreactivity in neuronal cell bodies and varicose fibers in the buccal ganglion of Navanax and that CCK-8 inhibits buccal ganglion neurons selectively and at tenth picomolar concentrations: expansion motoneurons responsible for prey capture are strongly inhibited by CCK-8; circumferential motoneurons responsible for swallowing are weakly inhibited by CCK-8. A large cell, cell X, is described which is sensitive to very low doses of CCK-8. These data imply the existence of a CCK-like peptide with transmitter-like actions in the buccal ganglion of Navanax.     

The depolarization-induced release of cholecystokinin C-terminal octapeptide (CCK-8) from rat synaptosomes and brain slices

Studies on the subcellular distribution of immunoreactive cholecystokinin (CCK) in homogenates of rat cerebral cortex showed that approximately 95% was associated with particulate fractions, including presynaptic terminals (synaptosomes). Chromatography of extracts of tissue and medium from incubated synaptosomes revealed that this material was almost exclusively in the form of COOH-terminal octapeptide (CCK-8), very little CCK-33 being present. There was a wide range of CCK-8 concentrations in synaptosomes from different brain regions (cortex > striatum ? hypothalamus > brain stem). Cerebral cortex synaptosomes were incubated in vitro and showed a complex pattern of CCK-8 release with varying concentrations of tissue: amounts in the medium rose rapidly with increasing synaptosome concentrations, then fell to a plateau at higher tissue values. A mechanism for the rapid disposal of extracellular CCK-8 was associated with synaptosomal fractions. Depolarization-induced (high K⁺) release of CCK-8 was observed with cortex and corpus striatum synaptosomes. A rapid and reversible enhancement of CCK-8 release from cortex slices was observed in response to elevated K⁺. Veratrine also released CCK-8 from cortex slices, although this was not reversible. Stimulus-induced release of CCK-8 from synaptosomes and slices required extracellular Ca²⁺. The storage, release and degradation of CCK-8 by nerve-endings suggest a synaptic function for this peptide.     

Rat immunoreactive cholecystokinin (CCK): characterization using two chromatographic techniques

Acid and neutral extracts of rat cerebral cortex and upper small intestine were prepared and the endogenous concentrations of cholecystokinin-like immunoreactivity (CCK-LI) measured by three new CCK-specific radioimmunoassays. The characterization of the immunoreactive CCK molecular forms was undertaken using gel permeation chromatography in the presence of 6 M urea to minimise problems relating to peptide adsorption or aggregation. Reverse-phase high-performance liquid chromatography (HPLC) was also performed on the rat tissue extracts. Rat cortex contained 268 +/- 12 pmol/g CCK-LI, and over 90% resembled the sulphated CCK-8, which was preferentially extracted at neutral pH. In contrast, the rat upper small intestine (97 +/- 8 pmol/g of CCK-LI) contained less than 20% CCK-8, the majority of immunoreactive CCK being of larger molecular size and being preferentially extracted at acid pH. In the small intestine the predominant molecular form(s) was intermediate in size between CCK-33 and CCK-8. Large amounts of CCK-33 and of a molecular form larger than CCK-33 were also detected. It is concluded that post-translational cleavage of CCK differs in rat brain and gut.     

Cholecystokinin Stimulates Dopamine Synthesis in Synaptosomes by a Cyclic AMP-Dependent Mechanism

The effects of different fragments of cholecystokinin (CCK) on dopamine synthesis were studied in synaptosomal preparations from the striatum, substantia nigra, and frontal cortex. In striatal synaptosomes, dopamine synthesis rate measured by dopamine accumulation was 12.5% lower than that measured by 3,4-dihydroxyphenylalanine (DOPA) accumulation; however, K+-accelerated synthesis was the same for both methods. Synthesis rate was independent of exogenous tyrosine levels. In the three regions studied, the combined stimulatory effects of 8-Br-cyclic AMP and high K+ were additive. CCK-5, CCK-3, CCK-27-33, and CCK-8 (sulphated) enhanced synthesis, CCK-5 being the most potent fragment. The nonsulphated octapeptide had no effect. In all three regions, CCK-5 and high K+ had an additive effect on dopamine synthesis; CCK-5 and 8-Br-cyclic AMP together produced the same enhancement of synthesis as CCK-5 alone. CCK-5 produced similar dose-dependent increases in dopamine synthesis and cyclic AMP accumulation in striatal synaptosomes, and both effects were blocked by the CCK antagonist proglumide.     

Brain CCK receptors: species differences in regional distribution and selectivity

The binding of 125I-CCK-33 to its receptors prepared from cerebral cortex and cerebellum was studied in four species: mouse, rat, hamster, and guinea pig. Only the guinea pig showed significant binding to membranes from cerebellum and this binding was comparable to that observed for cerebral cortex. In all four species, the order of potency of unlabeled analogs to compete for the binding site was CCK-8 greater than CCK-33 greater than desulfated CCK-8 greater than CCK-4. While the affinity for CCK-8 and CCK-33 was similar in the various species, the relative affinity for desulfated CCK-8 and CCK-4 was less for hamster and guinea pig, indicating species differences in receptor specificity, as well as in regional localization.     

A method for studying synaptosomal release of neurotransmitter candidates, as evaluated by studies on cortical cholecystokinin octapeptide release

A method for perfusing rat cortical synaptosomes for studying the regulation of cholecystokinin octapeptide (CCK-8) release has been developed and was found to have advantages over the static incubation system. Synaptosomes isolated from rat cortex were suspended in Biogel P2 columns and perfused with Krebs Ringer Bicarbonate buffer. One hundred mM KCl and 75 microM veratine stimulated CCK-8 release, which was Ca++-dependent. The synaptosomes were functionally viable for at least 135 min of incubation as indicated by multiple 100 mM KCl depolarizations and uptake of (3H)-norepinephrine and (14C)-choline. Dopamine and acetylcholine (10(-6)M) stimulated CCK-8 release while serotonin and norepinephrine were without effect. Approximately 20% of total occluded CCK-8 was released from synaptosomes by 100 mM KCl and degradation of CCK-8 was less than 10%. Perfusion of synaptosomes has several advantages over static incubation systems and allows systematic studies on the role of neurotransmitter in the regulation of neuropeptide secretion.     

In vivo synthesis of cholecystokinin in the rat cerebral cortex: identification of COOH-terminal peptides with labeled amino acids

The synthesis of the COOH-terminal octa- and tetrapeptides of cholecystokinin (CCK) has been studied in rat cerebral cortex after intraventricular administration of radioactive amino acids characteristic of the porcine COOH-terminal octapeptide of CCK, CCK-8. After immunosorption with a COOH-terminal directed antibody, cortical CCK was fractionated on Sephadex G-50 columns. The experiments demonstrated newly synthesized CCK forms which coeluted with porcine CCK-8 and CCK-4. Except for threonine the amino acids employed, methionine, tryptophan, aspartic acid, glycine and phenylalanine were incorporated. The sequence-specific radioimmunoassay, the incorporation of the employed labeled amino acids, and the elution pattern by gel filtration, suggest an almost identical structure of porcine and rat cortical CCK-8, and a concomitant synthesis of CCK-8 and CCK-4 in rat cerebral cortex.     

In vivo biosynthesis of cholecystokinin in hog cerebral cortex

The biosynthesis of cholecystokinin (CCK) in the cerebral cortex of hogs was studied by intracisternal injections of [³⁵S]methionine. At different times (15, 60 and 120 min) after the injection, cortex was isolated and extracted with boiling water and 0.5 M acetic acid. CCK in the extracts was immunosorbed, using an antiserum specific for the COOH-terminal sequence of CCK. Subsequently, the CCK-immunoreactivity was applied to Sephadex G-50 superfine columns. The fractionation showed incorporation in five molecular forms with elution constants of 0.08, 0.50, 0.90, 1.1 and 1.3. After a pulse period of 15 min, [³⁵S]methionine was incoporated mainly into the largest form of CCK (K_av of 0.08). The incorporation in all forms increased during the first hour. After 2 hours, a decline occurred in the larger forms, whereas the incorporation in the octapeptide form and tetrapeptide-like form increased.     

Specificity of nucleus accumbens to activities related to cholecystokinins in rats

Cholecystokinin octapeptide (CCK-8) or cholecystokinin tetrapeptide (CCK-4) were bilaterally injected into the areas where dopamine (DA) terminals and receptors have been detected; nucleus accumbens (NA), nucleus caudatus (NC), medial profrontal cortex (MPC), or prefrontal cortex (PC). The amount injected to each animal varied from 0 (control), 1 to 500 ng of CCK-8 and 0 (saline control), 0.5 to 2.5 micrograms of CCK-4 in NA in a volume of 1 microliter. The other areas received 500 ng CCK-8, 2.5 micrograms CCK-4 and proper control injections. The effects were observed in an open-field apparatus by measuring locomotor and rearing responses, the latency to move out of a specified area where the animal was first placed, and the amount of excretory bolus during a 5 min period following injections. When injected into NA, CCK-8 decreased locomotion and rearing at doses of 2.5 ng or more in a dose-related manner whereas CCK-4 increased locomotion and rearing at 1 microgram or more. The effects on latency and defecation were not detected. When the peptides were injected into NC, MPC or PC no effects were detectable. It appears that the effects of CCK-8 and CCK-4 on the exploratory responses are site-specific at NA where CCK-8 and DA are found to coexist in same neurons. CCK-4, a metabolite of CCK-8, could exert a negative feedback to moderate the effect of CCK-8.     

Acute and long-lasting effects of peripheral injection of caerulein and CCK-8 on the central GABAergic system in mice

Acute and long-lasting effects of peripheral injection of caerulein (CLN) and cholecystokinin octapeptide (CCK-8) on the gamma-aminobutylic acid (GABA) content and the GABA accumulation by aminooxyacetic acid (AOAA) in the discrete brain regions of mice were examined. The content and accumulation of GABA in the striatum, hypothalamus, and frontal cortex was measured with high performance liquid chromatography with electrochemical detection (HPLC-ECD). The GABA content slightly decreased in the striatum 60 min after CLN and CCK-8 were administered, whereas it slightly increased in the hypothalamus and frontal cortex. Moreover, with CLN and CCK-8, the GABA accumulation after AOAA treatment decreased in the striatum and hypothalamus 30 min after injection. Meanwhile, when administering CLN, the GABA content as well as the GABA accumulation after AOAA treatment increased in the striatum and frontal cortex 1 day after injection, and continued to increase the second and third day in the striatum. These results showed that peripheral injection of CLN and CCK-8 had effects on the central GABAergic system with local specific actions, and also the long-lasting and time-dependent biphasic effects of CLN.     

Relationship of CCK/gastrin receptor binding to amylase release in dog pancreatic acini

Effects of synthetic peptides belonging to the CCK/gastrin family (CCK-39, CCK-8, G/CCK-4, G-17ns) on amylase release in dog pancreatic acini have been measured and correlated with binding of three radio-labelled CCK/gastrin peptides: ¹²⁵I-BH-(Thr,Nle)-CCK-9, ¹²⁵I-BH-(2–17)G-17ns and ¹²⁵I-BH-G/CCK-4 prepared by conjugation of the peptides to iodinated Bolton-Hunter reagent and purified by reverse-phase-HPLC. All the CCK/gastrin peptides produced the same maximal amylase release response. Half-maximal responses (D₅₀) were obtained with 2 · 10^?10 M CCK-8; 6 · 10^?10 M CCK-39; 10^?7 M G.17 ns and 2 · 10^?6 M G/CCK-4. Dose-response curves for G-17 ns and G/CCK-4 were similar in configuration but not parallel with those for CCK-8 and CCK-39.Binding studies with ¹²⁵I-BH(Thr,Nle)-CCK-9 demonstrated the presence of specific CCK receptors on dog pancreatic acini. There was a good correlation between receptor occupancy by CCK-8 and CCK-39 and amylase stimulation since maximal amylase stimulation was achieved when 40–50% of high affinity receptors were occupied. In contrast, a saturation of these receptors was required for maximal stimulation by G-17 ns and G/CCK-4 suggesting the existence of a fraction of receptors that can be occupied by G-17 ns and G/CCK-4 without stimulation of amylase release. Binding studies with labelled (2–17)-G-17 ns and G/CCK-4 confirmed the presence of high affinity sites for G-17 ns and G/CCK-4. These sites were not related to amylase release.This study points out a possible species specificity of biological action of gastrin/CCK peptides on pancreatic exocrine secretion in higher mammals.     

Cholecystokinin octapeptide: Vesicular localization and calcium dependent release from rat brain in vitro

Sub-cellular fractionation tissue from rat hypothalamus and cerebral cortex in sucrose gradients indicated a concentration of cholecystokinin-like peptides in synaptosomal fractions. Lysis of synaptosomes yielded a vesicle rich fraction which was further enriched in cholecystokinin-like peptides, particularly the octapeptide (CCK-8). In vitro release experiments carried out using rat cerebral cortex tissue slices showed a calcium dependent release of cholecystokinin (primarily as CCK-8). The demonstration of a vesicular localization and calcium evoked release of cholecystokinin is consistent with a role for cholecystokinin as a neurotransmitter/neuromodulator in the CNS.     

Characterization of preprocholecystokinin products in the porcine cerebral cortex. Evidence of different processing pathways

Using gel, ion-exchange, and reverse-phase chromatography monitored by radioimmunoassays specific for five sequences of preprocholecystokinin (prepro-CCK), its processing products were measured in neutral and acid extracts of porcine cerebral cortex before and after incubation with trypsin, carboxypeptidase B, and arylsulfatase. Three categories of peptides were found: biologically active peptides, i.e. peptides with the alpha-amidated COOH terminus Trp-Met-Asp-Phe-NH2, comprising large CCKs, i.e. peptides larger than CCK-58 and peptides eluting like CCK-58, CCK-33, and CCK-22; CCK-octapeptides in sulfated and traces of nonsulfated forms; and small CCKs, i.e. traces of CCK-7, large amounts of CCK-5, and modest concentrations of CCK-4 (the structures of CCK-5 and -4 were confirmed by sequence analysis); four NH2-terminal fragments, of which the two predominant ones correspond to the desnonapeptide fragments of CCK-58 and CCK-33; and COOH-terminal extended peptides corresponding to glycine-extended CCK-58, CCK-33, and CCK-8 in small but significant amounts. Thus, in addition to CCK-8 the porcine cerebral cortex synthesizes larger and smaller active CCK peptides in quantities of an order similar to those of CCK-8. The occurrence of these together with the NH2-terminal fragments and glycine-extended peptides can be explained only by the existence of different processing pathways for preproCCK. Consequently, the results suggest that cerebral CCK neurons are heterogeneous and comprise at least three populations with different biosynthetic machineries.     

Chemical characterization of rat cholecystokinin-58

Cholecystokinin-58 (CCK-58) was purified from rat intestines using an extraction method that yields large amounts of this peptide. Greater than 30% of total CCK immunoreactivity eluted before CCK-39 upon gel permeation chromatography (Sephadex G-50) if extracts were loaded onto Sep Pak cartridges before freezing. If the extracts were frozen and stored at −70°C for six weeks, only 20% of the material eluted in this region and total immunoreactivity was reduced by 50%, suggesting that proteases were active under these storage conditions. This early eluting peak was purified by reverse phase and ion-exchange HPLC to a single absorbance peak. Microsequence analysis of this peak detected AVLRPDSEP which is the amino terminus of rat CCK-58 predicted from the rat preprocholecystokinin cDNA. Because degradation of CCK-58 occurred in these extracts, it is possible that CCK-58 is the predominant molecule form in the rat small intestine.     

Somatostatin and CCK-8 modulate release of striatal amino acids: role of dopamine receptors

The effects of somatostatin (SOM) and cholecystokinin octapeptide (CCK-8) on basal and potassium-evoked release of neurotransmitter amino acids were investigated in slices of rat caudate nucleus (CN) and, for comparison, cerebral cortex (CX). Endogenous aspartate (Asp), glutamate (Glu), glycine (Gly), and gamma-aminobutyric acid (GABA) were measured by high performance liquid chromatography. In both CN and CX, potassium (5-55 mM) produced a concentration-dependent increase in the release of Asp, Glu, Gly, and GABA in the presence of extracellular Ca2+. CCK-8 (1 microM) stimulated in CN the basal and K+-evoked release of Gly to 231% and 160% of control, respectively; this effect was blocked by sulpiride (SULP), a dopamine receptor antagonist. In contrast, SOM (1 microM) inhibited the K+-evoked release of Glu in CN by 26%, an effect that was not blocked by SULP. SOM and CCK-8 did not significantly affect the basal or K+ (35 mM)-evoked release of other amino acids in the CN or of any amino acids in CX. The results indicate that: CCK-8 facilitation of Gly release is dependent of Gly release is dependent on dopamine receptor activation, whereas the inhibition by SOM of Glu release is not: and the effects of SOM and CCK-8 are specific with respect to the brain region affected.     

Heterogeneous effects of cholecystokinin on neuronal response properties in deep layers of rat barrel cortex

Abstract

Cholecystokinin (CCK) is one of the most studied neuropeptides in the brain. In this study, we investigated the effects of CCK-8s and LY225910 (CCK₂ receptor antagonist) on properties of neuronal response to natural stimuli (whisker deflection) in deep layers of rat barrel cortex. This study was done on 20 male Wistar rats, weighing 230–260?g. CCK-8s (300?nmol/rat) and LY225910 (1?µmol/rat) were administered intracerebroventricularly (ICV). Neuronal responses to deflection of principal (PW) and adjacent (AW) whiskers were recorded in the barrel cortex using tungsten microelectrodes. Computer controlled mechanical displacement was used to deflect whiskers individually or in combination at 30?ms inter-stimulus intervals. ON and OFF responses for PW and AW deflections were measured. A condition-test ratio (CTR) was computed to quantify neuronal responses to whisker interaction. ICV administration of CCK-8s and LY225910 had heterogeneous effects on neuronal spontaneous activity, ON and OFF responses to PW and/or AW deflections, and CTR for both ON and OFF responses. The results of this study demonstrated that CCK-8s can modulate neuronal response properties in deep layers of rat barrel cortex probably via CCK₂ receptors.     

Time dependent changes in the concentrations of immunoreactives cholecystokinin octapeptide sulfate in rat brain regions after systemic injection of picrotoxin

Cholecystokinin octapeptide sulfate-like immunoreactivity (CCK-8S-LI) was determined by enzyme linked immunoassay (ELISA) in seven rat brain areas following injections subcutanously of the Cl^- channel blocker, picrotoxin. Time dependent changes in the concentrations of CCK-8S-LI were seen in the hippocampus, amygdaloid complex, septum, and hypothalamus at 15–180 min after the injection. Concentrations of CCK-8S-LI in the frontal cortex, striatum, and thalamus did not show significant changes. CCK-8S-LI in the amygdaloid complex and hypothalamus was the lowest concentrations at 60 min, and the concentrations in the hippocampus and septum were the lowest at 180 min. The data on high-performance liquid chromatography of the extracts from rat amygdaloid complex showed that changes in the concentrations of CCK-8S-LI were mainly due to the concentration of CCK-8S itself. These data indicate that systemic injection of picrotoxin decreases the concentration of CCK-8S in the brain regions, and the decreases in the amygdaloid complex and hypothalamus occur earlier than that in the hippocampus and septum.     

Characterization of cholecystokinin binding sites in rat cerebral cortex using a 125I-CCK-8 probe resistant to degradation

Specific binding sites for cholecystokinin (CCK) have been characterized in a particulate membrane fraction of rat cerebral cortex using a biologically active 125I-labeled derivative of the C-terminal octapeptide of CCK (CCK-8) prepared by reaction with the iodinated form of the imidoester (125IIE), methyl-p-hydroxybenzimidate. The time course of binding to cortical membranes was rapid, temperature dependent, and saturable. Half-maximal binding at 24 degrees C was reached in 30 min and full binding at 120 min. At 37 degrees C there was only a slight increase in 125IIE-CCK-8 bound after 15 min. The addition of a large excess of CCK-8 after 30 min of binding at 24 degrees C caused a prompt and rapid decline in radioligand bound showing that the interaction was reversible. There was a progressive decline in the amount of 125IIE-CCK-8 bound to membranes with increasing concentrations of CCK-8 and other structurally related peptides. CCK-8 displaced 50% of the radioligand at 4 nM, CCK-33 at 10 nM, and gastrin (desulfated CCK-8) at 60 nM. Secretin, a structurally unrelated peptide, was unable to displace the radioligand from cortical membranes at 1.0 microM. Finally, 125IIE-CCK-8 exposed to cortical membranes or to buffers that had previously contained such membranes for 60 min at 24 degrees C bound equally as well to fresh cortical membranes as control radioligand that had not been exposed to the same conditions. Thus the 125I-CCK-8 radioligand used in this study was highly resistant to degradative processes in rat brain tissue.