Which function describes the role of the hormone cholecystokinin?

Which function describes the role of the hormone cholecystokinin?

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Department of Clinical Biochemistry, Rigshospitalet, University of Copenhagen, DK-2100 Copenhagen, Denmark

Academic Editors: Jérôme Leprince, Hubert Vaudry and Billy KC Chow

Received: 15 July 2021 / Revised: 8 September 2021 / Accepted: 14 September 2021 / Published: 17 September 2021

Abstract

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The classic gut hormone cholecystokinin (CCK) and its CCK2-receptor are expressed in almost all regions of the brain. This widespread expression makes CCK by far the most abundant peptidergic transmitter system in the brain. This CNS-ubiquity has, however, complicated the delineation of the roles of CCK peptides in normal brain functions and neuropsychiatric diseases. Nevertheless, the common panic disorder disease is apparently associated with CCK in the brain. Thus, the C-terminal tetrapeptide fragment of CCK (CCK-4) induces, by intravenous administration in a dose-related manner, panic attacks that are similar to the endogenous attacks in panic disorder patients. This review describes the history behind the discovery of the panicogenic effect of CCK-4. Subsequently, the review discusses three unsettled questions about the involvement of cerebral CCK in the pathogenesis of anxiety and panic disorder, including therapeutic attempts with CCK2-receptor antagonists.

1. Introduction

Cholecystokinin (CCK) is an established gut hormone that stimulates gallbladder contraction and the emptying of bile into the small intestine [1], hence its name. CCK also regulates pancreatic enzyme secretion and growth, and it influences gastric emptying, intestinal motility, and satiety (for reviews, see [2,3,4]). On top of the essential gastrointestinal and pancreatic functions, the late 1970s showed—at that time surprisingly—that CCK is also a major neuropeptide in the central and peripheral nervous system [5,6,7,8,9,10].

The cerebral expression is unique among neuropeptides, in the sense that CCK in adult mammalian brains is abundantly present in all regions, except the cerebellum [9,10]. Moreover, the tissue concentrations, not least in the neocortical regions, are significantly higher than those measured for other neuropeptides [9,11]. In addition, the total amounts of CCK synthesized in the human brain are beyond those of the gut. CCK peptides have also turned out to be potent neurotransmitters [12,13]. As in the intestinal endocrine I-cells, CCK peptides in cerebral neurons mature from proCCK processing to different bioactive forms. CCK neurons have the short O-sulfated CCK-8 as the predominant form [6,9,14] and the shorter, nonsulfated CCK-5 as the second most abundant form [15,16]. In contrast, intestinal I-cells mainly release longer molecular forms (CCK-58, -33, and -22 in sulfated, as well as nonsulfated, variants [17,18,19]). The molecular size differences between the CCK peptides in endocrine gut cells and cerebral neurons are governed by the expression of prohormone convertases (PCs) along the secretory pathway within the cells. The endocrine I-cells mainly utilize PC 1/3, whereas CCK-neurons primarily use PC 2 in the cellular processing [20].

When it comes to the association of CCK with panic disorder, with a lifetime prevalence of 3.5% (5% in women and 2% in men) [21], a couple of observations are worth remembering. First, among brain regions in mammals, the amygdala plays a decisive role in fear and anxiety [22,23,24]. Accordingly, the centromedial amygdaloid nuclei are also particularly rich in networks of CCK neurons [10,25,26] and express high densities of CCK2-receptors [27,28,29]. Second, although CCK-8 in its sulfated form is the predominant cerebral form of CCK, and may by exogenous administration (of CCK-8S itself or its analogue, caerulein) cause anxiety and panic attacks [24,30,31], the short C-terminal tetrapeptide fragment, CCK-4, appears on a molar basis to be a more potent panicogenic peptide [24,30]. These observations and other unsettled questions will be discussed in the following.

2. The Bioactivity of CCK-4

The interest in the biological activity of the carboxyamidated tetrapeptide of CCK (Trp-Met-Asp-Phe·CONH2) dates back to the structural identification of another gastrointestinal hormone, the gastric acid regulatory hormone, gastrin [32,33]. Detailed structure–function studies of the identified gastrin-17 peptide revealed that the “active site” or receptor epitope of gastrin was precisely confined to the C-terminal tetrapeptide amide [34]. Thus, substitution of any of the four amino acid residues in the tetrapeptide (Trp, Met, Asp, Phe) reduced the acid-stimulatory activity markedly. A few years later, identification of the structure of intestinal CCK-33 showed a remarkable homology between gastrin-17 and CCK-33 [35,36]. Thus, CCK has exactly the same C-terminal bioactive tetrapeptide sequence as gastrin (Figure 1). Moreover, this common carboxyamidated sequence has been exceedingly well preserved during 600 million years of evolution [37,38,39,40], a fact that emphasizes the biological significance of the common tetrapeptide.

The discovery that the activity of gastrin could be mimicked by the smaller C-terminal tetrapeptide fragment in the 1960s [34] had two immediate consequences: First, the tetrapeptide was a considerably cheaper secretagogue to synthetize in comparison with the full-length gastrin-17 peptide, and gastrin was needed for clinical and basic studies of gastric acid secretion. The context in those years was that gastrin and its effect on acid secretion was essential for understanding the pathophysiology of the widespread duodenal ulcer disease. Along that line, the so-called “Pentagastrin®” was also synthetized. “Pentagastrin” is, however, a misnomer for a synthetic analogue with a BOC-Ala group coupled to the N-terminus of the authentic tetragastrin sequence (Figure 1). Second, some pharmaceutical companies synthesized tetragastrin analogues as possible drug targets for development of a gastrin receptor antagonist, to be used in the treatment of the gastric acid hypersecretion in duodenal ulcer patients that otherwise required major gastric surgery. However, a useful gastrin-4 based drug never materialized, and some pharmaceutical companies therefore had stocks of unused synthetic tetragastrin (alias CCK-4). One of these companies was the Danish LEO Pharmaceutical Products, who had prepared thousands of ampoules, each containing 70 µg of the tetrapeptide, to be injected as a bolus in dyspeptic ulcer patients for measurement of the gastric acid output.

In 1968, I wanted to study the effect of gastrin on insulin secretion after the rediscovery of incretin (incretin is the gut hormonal stimulation of insulin secretion [41,42] (for a recent review, see [43])). With limited funding, a generous gift of gastrin-4 ampoules from LEO Pharma was an appreciated help. Indeed, a bolus injection of gastrin-4 in healthy young men released considerably more insulin than a gastrin-17 preparation, in spite of similar effects on gastric acid secretion [44,45]. The potent insulinogenic effect of the tetrapeptide was later confirmed in more comprehensive studies using an isolated, perfused porcine pancreas [46].

Since gastrin-4 (identical with CCK-4) is a potent hormone releaser, since we had plenty of the tetrapeptide from LEO Pharma, and since we had observed CCK-neurons in the hypothalamus innervating the pituitary [10], we also wished to examine the effect of the tetrapeptide of growth hormone secretion. In a pilot experiment, I consequently injected a bolus of gastrin-/CCK-4 intravenously into myself and a colleague (Dr. Thue W. Schwartz). The effect on growth hormone secretion was small, but the “side” effect was dramatic.

3. The Panicogenic Activity of CCK-4

Half a minute after the injection of CCK-4, we experienced the beginning of what was to be a full-blown panic attack. The symptoms were intense anxiety, with a fear of dying, and a strange sense of the world sliding away, accompanied by palpitations, sweating, and faintness. The attack peaked after 5–8 min, and then gradually disappeared during the following 15–20 min [47]. None of us had experienced such an attack before. Of course, we wanted to follow it up. However, shortly after, my colleague moved to Chicago, and I got a busy chair in Copenhagen. In July 1984, however, Vanderhaeghen and Crawley organized an international conference on “Neuronal Cholecystokinin” in Brussels [48]. The last session of the conference was entitled “Clinical significance of neuronal cholecystokinin”. The chairman asked in the general discussion whether anyone in the audience beyond the session-speakers had observations of clinical interest. I therefore described the experienced panic attacks provoked by CCK-4. Present in the audience were also Jacques Bradwejn and Claude de Montigny from Montreal in Canada. In microiontophoretic studies in rat hippocampus they had recently observed that benzodiazepine antagonized CCK-8 (s)-induced activation of hippocampus neurons [49,50]. After the session, they contacted me about the CCK-4/panic story. I gave them information about further details of dose, injection, and symptoms. Working in psychiatry, they have since followed this up; first with systematic CCK-4 studies in healthy volunteers and patients with panic disorders [51,52,53]. Moreover, Bradwejn et al. subsequently performed dose ranging studies [54], showing that panic disorder patients have an increased sensitivity to CCK-4, and examined the therapeutic effect of CCK2-receptor antagonists (also including L-365, 260) [55]. Since then, the volume of clinical and experimental publications about CCK-4 and panic disorder has grown overwhelmingly, as also reflected in later reviews [56,57,58,59]. There is no doubt that Jacques Bradwejn played a leading role in this development.

Today, nobody questions CCK-4 as a robust panicogenic peptide, that is and has been a reliable tool in the study of panic disorder in man, and anxiety in most mammals. It is also well-established that CCK-4, of course, targets the cerebral CCK2-receptor and interacts in the provocation of anxiety with other neurotransmitter systems, such as the benzodiazepine/GABA complex, corticotropin-releasing factor, dopamine, noradrenaline, opioids, and serotonin [60,61,62,63,64,65,66,67]. Moreover, exogenous CCK-4 stimulates blood-flow in the anterior cingulate gyrus, the claustrum-insular-amygdala region, and the cerebellar vermis [68,69], and may act also at locus coeruleus and brainstem nuclei nucleus tractus solitarius, medulla, and parabranchial nuclei [70].

Regarding the CCK2-receptor binding, there is evidence that the receptor in patients with panic disorder may be more sensitive to CCK-4 and its analogue, pentagastrin [71,72,73]. Some genetic studies have also found variations in the genes encoding CCK and the CCK2-receptor [74,75,76,77,78,79].

So far, the use of synthetic CCK-4 in a high dose administered as an intravenous bolus (as described above) has been decisive for initiating the broad spectrum of investigations of the association between cerebral CCK and the widespread panic disorder in man. Moreover, a multitude of experimental anxiety-studies, not least in rodents, have used the CCK-4 approach. You might even ask whether significant knowledge about the CCK-panic disorder link would exist today without the serendipitously discovered effect of CCK-4.

4. Does the Brain Synthesize CCK-4 as a Separate Neuropeptide?

As mentioned above, the entirely dominant CCK-neurotransmitter is sulfated CCK-8 [9,14,16]. Beyond CCK-8 and small amounts of the longer forms (sulfated and nonsulfated CCK-58, -33, and -22 [15,80,81]), cerebral neurons, however, also synthesize the short CCK-5 (Gly-Trp-Met-Asp-Phe·NH2) in significant amounts [15,82]. However, an additional genuine neuronal synthesis of CCK-4 as such is questionable for different reasons: First, although the CCK-4 peptide has indeed been chemically identified in extracts of the porcine brain [15], the tissue concentrations were very low. Hence, the observed trace amounts of CCK-4 might well be a degradation product of CCK-5 occurring during extraction. CCK-4 differs from CCK-5 only by a single N-terminal glycyl residue (Figure 1). Second, so far no laboratory has managed to raise antibodies specific for the N-terminus of CCK-4. Such antibodies might by immunocytochemistry be decisive for the discussion of whether biosynthesis of CCK-4, as such, occurs in neurons. A third consideration concerns the N-terminal Trp-residue in CCK-4. The identified G-protein-coupled receptor, GPR142 [83], binds free tryptophan and to some extent also short peptides with an N-terminal Trp-residue. GPR142 is expressed in large amounts on pancreatic islet cells [84], where it seems to balance the effect of some gut hormones, including CCK, on insulin secretion [85]. Since CCK-4 more potently releases insulin than CCK-5 and the longer CCK-peptides [46], a mechanism might be that high dosing of exogenous CCK-4 simultaneously activates both the CCK2-receptor and GPR142 in pancreatic islets [84,86]. Whether the striking panicogenic potency of exogenous CCK-4 is due to a similar mechanism remains to be shown. If so, the lack of intracellular processing of CCK-5 to CCK-4 might make sense as a way to prevent severe panic attacks and anxiety.

5. Is Endogenous CCK in Plasma Associated with Panic Disorder?

CCK was, as mentioned, discovered as a gallbladder emptying gut hormone nearly a century ago [1]. Today, we know that the entire small intestine produces CCK in response to meals. We also know that essentially all the hormonally active CCK in plasma is derived from the CCK-producing endocrine I-cells in the gut [18]. Thus, even though endocrine cells in the pituitary, the thyroid C-cells, the adrenal medulla, and the testes express modest amounts of CCK [87,88,89,90,91], the extraintestinal endocrine cells contribute only marginally to the CCK in plasma.

The concentrations of bioactive CCK in mammalian plasma are low. In the fasting state, the concentrations vary from 0.1 to 2.0 pmol/L, and after a normal mixed meal, the concentrations increase to 5–7 pmol/L [92,93]. The molecular forms of CCK in human plasma are sulfated CCK-58, -33, -22, and -8, of which CCK-33 is the predominant form [18]. It is unlikely, but remains to be examined, whether any of these forms in their low picomolar plasma concentrations are able to penetrate the blood–brain barrier to any significant extent. Hence, the discrepancy with the peak in the high nanomolar range of CCK-4 concentrations in plasma after an intravenous bolus injection of 70 µg CCK-4 is enormous. It is, however, well known that sulfated CCK peptides in plasma, during and after a meal, signal satiety to the hypothalamus via CCK1-receptors on afferent vagal neurons [94,95]. Whether a similar neuronal mechanism, from peripheral plasma CCK to anxiety centers in the brain (amygdala), exists also remains to be studied.

6. CCK2-Receptor Antagonists in Panic Disorder Therapy

The realization that cerebral CCK2-receptors are the targets of CCK-4 in its induction of panic attacks clearly suggested examining receptor antagonists as therapeutic possibilities. So far, only a few antagonists have been studied. Interestingly, the well-established CCK2-receptor antagonist, L-365,260, reduced the panic response to the bolus of CCK-4 in patients suffering from panic disorders [55]. However, the reduction was observed only when L-365,260 was administered acutely, just before the injection of CCK-4. Placebo-controlled clinical trials showed no effect of L-365,260; presumably due to the limited bioavailability of the antagonist [96]. Along the same line, the CI-988 antagonist had only a weak effect on CCK-4-induced panic in healthy volunteers [97], but failed to affect patients with panic disorder [98]. In a recent study of anxiety in rats [99], the CCK2-receptor antagonist, LY-225,910, prevented the normalization of anxiety levels in rats. However, whether this antagonist also prevents attacks in panic disorder patients remains to be shown.

Generally, there is a problem in using systemic administration of CCK2-receptor antagonist in the therapy of panic disorder and other neuropsychiatric disorders, because CCK peptides and CCK2-receptors are so abundantly expressed in almost all regions of the brain [27,28,29,100] and not only in limbic structures, such as the amygdala. The blocking of the CCK-system (agonists and receptors) in the brain may have several serious effects, as shown in CCK knock-out mice, who apparently lose their memory (Jufang He, personal communication); and what is life without memory? At present, it seems difficult to overcome that kind of problem. Perhaps local administration of CCK2-receptor antagonists exclusively to the amygdala might help?

7. Conclusions

CCK peptides and the CCK2-receptor are, as mentioned, expressed at high levels in most brain regions, with marked densities in the cerebral cortex and limbic structures [9,10,27,28,29,100,101]. Since panic disorder is a rather common psychiatric condition, with a prevalence among women of 5% and 2% in men [21], you could argue that some involvement of the cerebral CCK-system in the pathogenesis of panic attacks should not come as a surprise. Nevertheless, it was unexpected that a simple intravenous bolus injection of the C-terminal tetrapeptide fragment of CCK should open the gates for decades of comprehensive studies of the role of CCK in panic disorder.

CCK-4 studies have unequivocally demonstrated that cerebral CCK-peptides and CCK2-receptors play a significant role in panic attacks. The studies have also shown that CCK-4 in high doses is a highly useful and reliable agent for provocation of panic attacks, both in healthy volunteers and panic disorder patients. In addition to CCK, however, it is now established that several other transmitter systems also are involved in the pathophysiology of panic attacks.

The story of CCK and panic disorders, however, has left several open questions. Among these, the present review has focused on three: Is CCK-4 a naturally occurring endogenous agonist for the cerebral CCK2-receptor? Second, is peripheral intestinal CCK in plasma associated with panic disorder? Finally, are CCK2-receptor antagonists useful drugs for panic disorder patients? This review suggests that CCK-4 as such, in contrast to CCK-5, can hardly be considered a natural product of biosynthesis in cerebral CCK neurons. Moreover, there is probably no association between the low CCK concentrations in plasma and panic disorder. Finally, no CCK-receptor antagonist has proved useful for therapy of panic disorder. Consequently, it is to be concluded that further basic and clinical research is necessary to answer these still unsettled questions.

Funding

This research received no external funding.

Institutional Review Board Statement

Not Applicable.

Not Applicable.

Data Availability Statement

Not Applicable.

Acknowledgments

The skillful and patient secretarial assistance of Connie Bundgaard (MA) is gratefully acknowledged.

Conflicts of Interest

The author declares no conflict of interest.

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Figure 1. The C-terminal amino acid sequences of members of the cholecystokinin family.

Figure 1. The C-terminal amino acid sequences of members of the cholecystokinin family.

Which function describes the role of the hormone cholecystokinin?

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What is the role of the hormone cholecystokinin?

It plays a fundamental role in the digestive process. When fats and proteins enter your small intestine, cholecystokinin triggers your gallbladder and pancreas to contract. They deliver bile and enzymes to your duodenum to help break down the food for absorption.

What are 3 functions actions of cholecystokinin?

Cholecystokinin is secreted by I-cells in the small intestine and induces contraction of the gallbladder, relaxes the sphincter of Oddi, increases bile acid production in the liver, delays gastric emptying, and induces digestive enzyme production in the pancreas.

What secretes the hormone cholecystokinin and what does it do?

Cholecystokinin is secreted by cells of the upper small intestine. Its secretion is stimulated by the introduction of hydrochloric acid, amino acids, or fatty acids into the stomach or duodenum. Cholecystokinin stimulates the gallbladder to contract and release stored bile into the intestine.

What hormone stimulates cholecystokinin?

CCK is the primary hormone responsible for gallbladder contraction and has potent effects on pancreatic secretion, gastric emptying, and satiety. In addition to fats, digested proteins and aromatic amino acids are major stimulants of CCK release.