Pharmacologists sometimes work in seemingly strange ways. Traditionally, you identify a new neurotransmitter and then search for the receptors for that transmitter. Sometimes, however, a receptor is discovered that is not responsive to any known neurotransmitter, hormone, or other signaling agent. Such a receptor is termed an orphan receptor. If you discover one of these, then you need to work “backwards,” in that you must try to find the neurotransmitter that activates your orphan receptor.
What if you discover a new receptor by virtue of its sensitivity to either a plant-derived substance or a synthetic drug? As an example, the existence of opioid receptors was hypothesized and subsequently proven based on the behavioral and physiological effects of morphine, a substance found only in the opium poppy. The same reasoning later led to the discovery of cannabinoid receptors, which are activated by the psychoactive substances present in cannabis plants. In this chapter, we have seen that there is a binding site on the GABAA receptor complex that is activated by BDZs, which are synthetic molecules. Even though this is an allosteric modulatory site, over a span of many years a small group of intrepid pharmacologists has searched for possible endogenous ligands for that binding site. If such compounds were discovered, it would mean that the BDZ modulatory site was a bona fide “receptor,” despite its modulatory properties.
The discovery of a BDZ binding site on the GABAA receptor more than 40 years ago prompted the eminent pharmacologist Leslie Iversen to hypothesize the existence of an anxiety-modulating substance within the brain (Iversen, 1977). During the intervening period, researchers have proposed several different candidate molecules that might serve this function (reviewed by Farzampour et al., 2015; Tonon et al., 2020). By far the major contender has been a large peptide (consisting of 86 amino acids) known as diazepam binding inhibitor (DBI) along with two smaller peptides that are derived from DBI. These smaller molecules are named octadecaneuropeptide (ODN), an 18 amino acid peptide consisting of DBI amino acid residues 33 to 50, and triakontatetraneuropeptide (TTN), a 34 amino acid peptide consisting of residues 17 to 50. Together, these compounds are often called endozepines, meaning endogenous BDZ-like substances (although their similarity to BDZs is based on their activity at the BDZ binding site, not their chemical structure). DBI was isolated from rat brain over 30 years ago on the basis of its ability to inhibit diazepam binding to the BDZ site on the GABAA receptor (Guidotti et al., 1983). Subsequent studies showed that DBI is not only present in the brains of many species, including humans, but is also widely distributed in peripheral tissues, including the liver, kidney, heart, intestine, and various endocrine glands (Bovolin et al., 1990; Costa and Guidotti, 1991; Ferrero et al., 1986a). Within the brain, DBI is synthesized and released mainly from astrocytes (Loomis et al., 2010; Yanase et al., 2002), although a few studies have also reported some expression in nerve cells.
Several early studies investigated the behavioral effects of DBI and ODN using the Vogel conflict test. This test involves training thirsty rats to drink water by licking a metal sipper tube and then giving them a mild shock through the tube. The degree of lick suppression is taken as a measure of the conflict (anxiety) produced by the electric shock. BDZs produce an anticonflict effect that is seen as an increased amount of post-shock licking (compared to untreated animals), presumably due to drug-induced enhancement of GABAA receptor function. In contrast, because BDZ inverse agonists reduce GABAA receptor activity, they produce a pro-conflict effect, manifested by decreased licking compared to control animals. Interestingly, when either DBI or ODN was administered directly into the brains of rats, a pro-conflict effect was observed (Guidotti et al., 1983; Ferrero et al., 1986b) (see Figure 1). Moreover, in both cases this effect was blocked by treatment with flumazenil, a BDZ antagonist. These findings indicate that DBI and ODN act as inverse agonists at the BDZ binding site in this behavioral test.
There is strong evidence that DBI is broken down into ODN or TTN after its release in the brain, and consequently that these smaller peptides (particularly ODN) are the primary behaviorally active substances in vivo. The initial studies summarized above suggested a role for endozepine peptides in the regulation of anxiety. Subsequent studies implicated DBI and/or ODN in a wide range of other behavioral and physiological processes, including anxiety, hunger and feeding behavior, pain perception, stress responses, drug addiction, and protection from brain insults (i.e., neuroprotection) (Tonon et al., 2020). Most of these effects are thought to be mediated through endozepine action at the BDZ binding site, although it is important to note that ODN has also been reported to activate a G protein–coupled metabotropic receptor in astrocytes that may be involved in the peptide’s inhibitory effect on food intake (do Rego et al., 2007; Hamdi et al., 2012).
Although the reported behavioral effects of DBI and the smaller DBI-derived peptides are intriguing, by themselves they fall short of confirming that these endozepines are truly endogenous ligands for the BDZ binding site. However, two subsequent studies by Christian and coworkers generated significant support for this hypothesis (Christian and Huguenard, 2013; Christian et al., 2013). The two studies focused on the reticular nucleus of the thalamus (nRT), a structure that plays a key role in regulating information transfer from the thalamus to the cortex via the thalamocortical projections. This regulatory function is mediated by GABAergic inhibition of the thalamic relay neurons, and dysregulation or blocking of GABAergic activity within the nRT causes abnormal electrical activity within the thalamus that can lead to absence seizures (seizures characterized by a brief loss of consciousness but lacking the powerful muscle contractions seen in grand mal seizures). The work of Christian and colleagues yielded the following results: (1) mutant mice lacking the gene that codes for DBI were more susceptible to developing (absence) seizure-like electrical discharges, (2) similar seizure susceptibility was observed in mice in which α3 subunit–containing GABAA receptors were disrupted (most GABAA receptors within the nRT contain this subunit), (3) replacing the DBI gene just in the nRT reversed the effect of the gene loss in the mutant mice, and (4) astrocytes are the likely source of DBI modulation of GABAergic activity within the nRT. Particularly surprising is the finding that in this model system, DBI acts as a positive allosteric modulator (i.e., an agonist, not an inverse agonist) of GABAA receptor activity. The discussion provided in the paper by Christian et al. (2013) offers several theories as to why inverse agonist (negative allosteric modulator) effects have been reported in other studies compared to theirs.
In summary, DBI peptides continue to be the strongest candidates for the long-sought-after endogenous ligand(s) for the BDZ binding site on the GABAA receptor. Studies of DBI activity within the nRT are currently the best in showing that endogenous synthesis and release of these peptides serves an important functional purpose. Indeed, the demonstrated regulation by DBI of thalamic electrophysiological activity and its role in suppressing seizure generation suggests that this peptide system could be a future target in the development of anti-epileptic drugs. The recent extensive review by Tonon and colleagues (2020) provides substantial evidence consistent with DBI and/or related peptides being true endogenous ligands for the BDZ binding site. Yet much more research needs to be conducted to determine the role of these compounds in normal behavioral and physiological regulation, as well as their potential contributions to pathological conditions.
References
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