Inverse agonist

Last updated
Dose response curves of a full agonist, partial agonist, neutral antagonist, and inverse agonist Inverse agonist 3.svg
Dose response curves of a full agonist, partial agonist, neutral antagonist, and inverse agonist

In pharmacology, an inverse agonist is a drug that binds to the same receptor as an agonist but induces a pharmacological response opposite to that of the agonist.

Contents

A neutral antagonist has no activity in the absence of an agonist or inverse agonist but can block the activity of either; [1] they are in fact sometimes called blockers (examples include alpha blockers, beta blockers, and calcium channel blockers). Inverse agonists have opposite actions to those of agonists but the effects of both of these can be blocked by antagonists. [2]

A prerequisite for an inverse agonist response is that the receptor must have a constitutive (also known as intrinsic or basal) level of activity in the absence of any ligand. [3] An agonist increases the activity of a receptor above its basal level, whereas an inverse agonist decreases the activity below the basal level.

The efficacy of a full agonist is by definition 100%, a neutral antagonist has 0% efficacy, and an inverse agonist has < 0% (i.e., negative) efficacy.

Examples

Receptors for which inverse agonists have been identified include the GABAA, melanocortin, mu opioid, histamine and beta adrenergic receptors. Both endogenous and exogenous inverse agonists have been identified, as have drugs at ligand gated ion channels and at G protein-coupled receptors.

Ligand gated ion channel inverse agonists

An example of a receptor site that possesses basal activity and for which inverse agonists have been identified is the GABAA receptors. Agonists for GABAA receptors (such as muscimol) create a relaxant effect, whereas inverse agonists have agitation effects (for example, Ro15-4513) or even convulsive and anxiogenic effects (certain beta-carbolines). [4] [5]

G protein-coupled receptor inverse agonists

Two known endogenous inverse agonists are the Agouti-related peptide (AgRP) and its associated peptide Agouti signalling peptide (ASIP). AgRP and ASIP appear naturally in humans and bind melanocortin receptors 4 and 1 (Mc4R and Mc1R), respectively, with nanomolar affinities. [6]

The opioid antagonists naloxone and naltrexone act as neutral antagonists of the mu opioid receptors under basal conditions, but as inverse agonists when an opioid such as morphine as bound to the same channel. 6α-naltrexo, 6β-naltrexol, 6β-naloxol, and 6β-naltrexamine acted neutral antagonists regardless of opioid binding and caused significantly reduced withdrawal jumping when compared to naloxone and naltrexone. [7]

Nearly all antihistamines acting at H1 receptors and H2 receptors have been shown to be inverse agonists. [8]

The beta blockers carvedilol and bucindolol have been shown to be low level inverse agonists at beta adrenoceptors. [8]

Mechanisms of action

Figure 2: Example of changes in Intrinsic activity based on mutations and the presence of inverse agonists. (assuming the inverse agonist has the same binding affinity for both the normal and mutated receptor) Basal activity of receptor changes.png
Figure 2: Example of changes in Intrinsic activity based on mutations and the presence of inverse agonists. (assuming the inverse agonist has the same binding affinity for both the normal and mutated receptor)

Like agonists, inverse agonists have their own unique ways of inducing pharmacological and physiological responses depending on many factors, such as the type of inverse agonist, the type of receptor, mutants of receptors, binding affinities and whether the effects are exerted acutely or chronically based on receptor population density. [9] Because of this, they exhibit a spectrum of activity below the Intrinsic activity level. [9] [10] Changes in constitutive activity of receptors affect response levels from ligands like inverse agonists. [11]

To illustrate, mechanistic models have been made for how inverse agonists induce their responses on G protein-coupled receptors (GPCRs). Many types of Inverse agonists for GPCRs have been shown to exhibit the following conventionally accepted mechanism.

Based on the Extended Ternary complex model, the mechanism contends that inverse agonists switch the receptor from an active state to an inactive state by undergoing conformational changes. [12] Under this model, current thinking is that the GPCRs can exist in a continuum of active and inactive states when no ligand is present. [12] Inverse agonists stabilize the inactive states, thereby suppressing agonist-independent activity. [12] However, the implementation of 'constitutively active mutants' [12] of GPCRs change their intrinsic activity. [9] [10] Thus, the effect an inverse agonist has on a receptor depends on the basal activity of the receptor, assuming the inverse agonist has the same binding affinity (as shown in the figure 2).

See also

Related Research Articles

<span class="mw-page-title-main">G protein-coupled receptor</span> Class of cell surface receptors coupled to G-protein-associated intracellular signaling

G protein-coupled receptors (GPCRs), also known as seven-(pass)-transmembrane domain receptors, 7TM receptors, heptahelical receptors, serpentine receptors, and G protein-linked receptors (GPLR), form a large group of evolutionarily related proteins that are cell surface receptors that detect molecules outside the cell and activate cellular responses. They are coupled with G proteins. They pass through the cell membrane seven times in form of six loops of amino acid residues, which is why they are sometimes referred to as seven-transmembrane receptors. Ligands can bind either to the extracellular N-terminus and loops or to the binding site within transmembrane helices. They are all activated by agonists, although a spontaneous auto-activation of an empty receptor has also been observed.

<span class="mw-page-title-main">Agonist</span> Chemical which binds to and activates a biochemical receptor

An agonist is a chemical that activates a receptor to produce a biological response. Receptors are cellular proteins whose activation causes the cell to modify what it is currently doing. In contrast, an antagonist blocks the action of the agonist, while an inverse agonist causes an action opposite to that of the agonist.

<span class="mw-page-title-main">Receptor (biochemistry)</span> Protein molecule receiving signals for a cell

In biochemistry and pharmacology, receptors are chemical structures, composed of protein, that receive and transduce signals that may be integrated into biological systems. These signals are typically chemical messengers which bind to a receptor and produce physiological responses such as change in the electrical activity of a cell. For example, GABA, an inhibitory neurotransmitter inhibits electrical activity of neurons by binding to GABAA receptors. There are three main ways the action of the receptor can be classified: relay of signal, amplification, or integration. Relaying sends the signal onward, amplification increases the effect of a single ligand, and integration allows the signal to be incorporated into another biochemical pathway.

<span class="mw-page-title-main">Receptor antagonist</span> Type of receptor ligand or drug that blocks a biological response

A receptor antagonist is a type of receptor ligand or drug that blocks or dampens a biological response by binding to and blocking a receptor rather than activating it like an agonist. Antagonist drugs interfere in the natural operation of receptor proteins. They are sometimes called blockers; examples include alpha blockers, beta blockers, and calcium channel blockers. In pharmacology, antagonists have affinity but no efficacy for their cognate receptors, and binding will disrupt the interaction and inhibit the function of an agonist or inverse agonist at receptors. Antagonists mediate their effects by binding to the active site or to the allosteric site on a receptor, or they may interact at unique binding sites not normally involved in the biological regulation of the receptor's activity. Antagonist activity may be reversible or irreversible depending on the longevity of the antagonist–receptor complex, which, in turn, depends on the nature of antagonist–receptor binding. The majority of drug antagonists achieve their potency by competing with endogenous ligands or substrates at structurally defined binding sites on receptors.

<span class="mw-page-title-main">Opioid receptor</span> Group of biological receptors

Opioid receptors are a group of inhibitory G protein-coupled receptors with opioids as ligands. The endogenous opioids are dynorphins, enkephalins, endorphins, endomorphins and nociceptin. The opioid receptors are ~40% identical to somatostatin receptors (SSTRs). Opioid receptors are distributed widely in the brain, in the spinal cord, on peripheral neurons, and digestive tract.

GABA<sub>A</sub> receptor Ionotropic receptor and ligand-gated ion channel

The GABAA receptor (GABAAR) is an ionotropic receptor and ligand-gated ion channel. Its endogenous ligand is γ-aminobutyric acid (GABA), the major inhibitory neurotransmitter in the central nervous system. Upon opening, the GABAA receptor on the postsynaptic cell is selectively permeable to chloride ions (Cl) and, to a lesser extent, bicarbonate ions (HCO3). Depending on the membrane potential and the ionic concentration difference, this can result in ionic fluxes across the pore. If the membrane potential is higher than the equilibrium potential (also known as the reversal potential) for chloride ions, when the receptor is activated Cl will flow into the cell. This causes an inhibitory effect on neurotransmission by diminishing the chance of a successful action potential occurring at the postsynaptic cell. The reversal potential of the GABAA-mediated inhibitory postsynaptic potential (IPSP) in normal solution is −70 mV, contrasting the GABAB IPSP (-100 mV).

Functional selectivity is the ligand-dependent selectivity for certain signal transduction pathways relative to a reference ligand at the same receptor. Functional selectivity can be present when a receptor has several possible signal transduction pathways. To which degree each pathway is activated thus depends on which ligand binds to the receptor. Functional selectivity, or biased signaling, is most extensively characterized at G protein coupled receptors (GPCRs). A number of biased agonists, such as those at muscarinic M2 receptors tested as analgesics or antiproliferative drugs, or those at opioid receptors that mediate pain, show potential at various receptor families to increase beneficial properties while reducing side effects. For example, pre-clinical studies with G protein biased agonists at the μ-opioid receptor show equivalent efficacy for treating pain with reduced risk for addictive potential and respiratory depression. Studies within the chemokine receptor system also suggest that GPCR biased agonism is physiologically relevant. For example, a beta-arrestin biased agonist of the chemokine receptor CXCR3 induced greater chemotaxis of T cells relative to a G protein biased agonist.

<span class="mw-page-title-main">Ligand (biochemistry)</span> Substance that forms a complex with a biomolecule

In biochemistry and pharmacology, a ligand is a substance that forms a complex with a biomolecule to serve a biological purpose. The etymology stems from Latin ligare, which means 'to bind'. In protein-ligand binding, the ligand is usually a molecule which produces a signal by binding to a site on a target protein. The binding typically results in a change of conformational isomerism (conformation) of the target protein. In DNA-ligand binding studies, the ligand can be a small molecule, ion, or protein which binds to the DNA double helix. The relationship between ligand and binding partner is a function of charge, hydrophobicity, and molecular structure.

A receptor activated solely by a synthetic ligand (RASSL) or designer receptor exclusively activated by designer drugs (DREADD), is a class of artificially engineered protein receptors used in the field of chemogenetics which are selectively activated by certain ligands. They are used in biomedical research, in particular in neuroscience to manipulate the activity of neurons.

κ-opioid receptor Protein-coding gene in the species Homo sapiens, named for ketazocine

The κ-opioid receptor or kappa opioid receptor, abbreviated KOR or KOP for its ligand ketazocine, is a G protein-coupled receptor that in humans is encoded by the OPRK1 gene. The KOR is coupled to the G protein Gi/G0 and is one of four related receptors that bind opioid-like compounds in the brain and are responsible for mediating the effects of these compounds. These effects include altering nociception, consciousness, motor control, and mood. Dysregulation of this receptor system has been implicated in alcohol and drug addiction.

Melanocortin receptors are members of the rhodopsin family of 7-transmembrane G protein-coupled receptors.

Neurotensin receptors are transmembrane receptors that bind the neurotransmitter neurotensin. Two of the receptors encoded by the NTSR1 and NTSR2 genes contain seven transmembrane helices and are G protein coupled. Numerous crystal structures have been reported for the neurotensin receptor 1 (NTS1). The third receptor has a single transmembrane domain and is encoded by the SORT1 gene.

<span class="mw-page-title-main">Growth hormone secretagogue receptor</span> Protein-coding gene in the species Homo sapiens

Growth hormone secretagogue receptor(GHS-R), also known as ghrelin receptor, is a G protein-coupled receptor that binds growth hormone secretagogues (GHSs), such as ghrelin, the "hunger hormone". The role of GHS-R is thought to be in regulating energy homeostasis and body weight. In the brain, they are most highly expressed in the hypothalamus, specifically the ventromedial nucleus and arcuate nucleus. GSH-Rs are also expressed in other areas of the brain, including the ventral tegmental area, hippocampus, and substantia nigra. Outside the central nervous system, too, GSH-Rs are also found in the liver, in skeletal muscle, and even in the heart.

<span class="mw-page-title-main">Antihistamine</span> Drug that blocks histamine or histamine agonists

Antihistamines are drugs which treat allergic rhinitis, common cold, influenza, and other allergies. Typically, people take antihistamines as an inexpensive, generic drug that can be bought without a prescription and provides relief from nasal congestion, sneezing, or hives caused by pollen, dust mites, or animal allergy with few side effects. Antihistamines are usually for short-term treatment. Chronic allergies increase the risk of health problems which antihistamines might not treat, including asthma, sinusitis, and lower respiratory tract infection. Consultation of a medical professional is recommended for those who intend to take antihistamines for longer-term use.

<span class="mw-page-title-main">Melanocortin 4 receptor</span> Mammalian protein found in Homo sapiens

Melanocortin 4 receptor (MC4R) is a melanocortin receptor that in humans is encoded by the MC4R gene. It encodes the MC4R protein, a G protein-coupled receptor (GPCR) that binds α-melanocyte stimulating hormone (α-MSH). In mouse models, MC4 receptors have been found to be involved in feeding behaviour, the regulation of metabolism, sexual behaviour, and male erectile function.

<span class="mw-page-title-main">Melanocortin 3 receptor</span> Mammalian protein found in Homo sapiens

Melanocortin 3 receptor (MC3R) is a protein that in humans is encoded by the MC3R gene.

5-HT<sub>7</sub> receptor Protein-coding gene in the species Homo sapiens

The 5-HT7 receptor is a member of the GPCR superfamily of cell surface receptors and is activated by the neurotransmitter serotonin (5-hydroxytryptamine, 5-HT) The 5-HT7 receptor is coupled to Gs (stimulates the production of the intracellular signaling molecule cAMP) and is expressed in a variety of human tissues, particularly in the brain, the gastrointestinal tract, and in various blood vessels. This receptor has been a drug development target for the treatment of several clinical disorders. The 5-HT7 receptor is encoded by the HTR7 gene, which in humans is transcribed into 3 different splice variants.

<span class="mw-page-title-main">Proxyfan</span> Chemical compound

Proxyfan is a histamine H3 receptor ligand which is a "protean agonist", producing different effects ranging from full agonist, to antagonist, to inverse agonist in different tissues, depending on the level of constitutive activity of the histamine H3 receptor. This gives it a complex activity profile in vivo which has proven useful for scientific research.

A cannabinoid receptor antagonist, also known simply as a cannabinoid antagonist or as an anticannabinoid, is a type of cannabinoidergic drug that binds to cannabinoid receptors (CBR) and prevents their activation by endocannabinoids. They include antagonists, inverse agonists, and antibodies of CBRs. The discovery of the endocannabinoid system led to the development of CB1 receptor antagonists. The first CBR inverse agonist, rimonabant, was described in 1994. Rimonabant blocks the CB1 receptor selectively and has been shown to decrease food intake and regulate body-weight gain. The prevalence of obesity worldwide is increasing dramatically and has a great impact on public health. The lack of efficient and well-tolerated drugs to cure obesity has led to an increased interest in research and development of CBR antagonists. Cannabidiol (CBD), a naturally occurring cannabinoid, is a non-competitive CB1/CB2 receptor antagonist. And Δ9-tetrahydrocannabivarin (THCV), a naturally occurring cannabinoid, modulate the effects of THC via direct blockade of cannabinoid CB1 receptors, thus behaving like first-generation CB1 receptor inverse agonists, such as rimonabant. CBD is a very low-affinity CB1 ligand, that can nevertheless affect CB1 receptor activity in vivo in an indirect manner, while THCV is a high-affinity CB1 receptor ligand and potent antagonist in vitro and yet only occasionally produces effects in vivo resulting from CB1 receptor antagonism. THCV has also high affinity for CB2 receptors and signals as a partial agonist, differing from both CBD and rimonabant.

A receptor modulator, or receptor ligand, is a general term for a substance, endogenous or exogenous, that binds to and regulates the activity of chemical receptors. They are ligands that can act on different parts of receptors and regulate activity in a positive, negative, or neutral direction with varying degrees of efficacy. Categories of these modulators include receptor agonists and receptor antagonists, as well as receptor partial agonists, inverse agonists, orthosteric modulators, and allosteric modulators, Examples of receptor modulators in modern medicine include CFTR modulators, selective androgen receptor modulators (SARMs), and muscarinic ACh receptor modulators.

References

  1. Kenakin T (April 2004). "Principles: receptor theory in pharmacology". Trends in Pharmacological Sciences. 25 (4): 186–92. doi:10.1016/j.tips.2004.02.012. PMID   15063082.
  2. Nutt D, Stahl S, Blier P, Drago F, Zohar J, Wilson S (January 2017). "Inverse agonists - What do they mean for psychiatry?". European Neuropsychopharmacology. 27 (1): 87–90. doi:10.1016/j.euroneuro.2016.11.013. hdl: 10044/1/43624 . PMID   27955830. S2CID   25113284.
  3. Berg, Kelly A; Clarke, William P (2018-08-06). "Making Sense of Pharmacology: Inverse Agonism and Functional Selectivity". International Journal of Neuropsychopharmacology. 21 (10): 962–977. doi:10.1093/ijnp/pyy071. ISSN   1461-1457. PMC   6165953 . PMID   30085126.
  4. Mehta AK, Ticku MK (August 1988). "Ethanol potentiation of GABAergic transmission in cultured spinal cord neurons involves gamma-aminobutyric acid voltage-gated chloride channels". The Journal of Pharmacology and Experimental Therapeutics. 246 (2): 558–64. PMID   2457076. Archived from the original on 2021-05-31. Retrieved 2008-04-21.
  5. Sieghart W (January 1994). "Pharmacology of benzodiazepine receptors: an update". Journal of Psychiatry & Neuroscience. 19 (1): 24–9. PMC   1188559 . PMID   8148363.
  6. Ollmann MM, Lamoreux ML, Wilson BD, Barsh GS (February 1998). "Interaction of Agouti protein with the melanocortin 1 receptor in vitro and in vivo". Genes & Development. 12 (3): 316–30. doi:10.1101/gad.12.3.316. PMC   316484 . PMID   9450927.
  7. Wang OD, Raehal KM, Bilsky EJ, Sadée W (June 2001). "Inverse agonists and neutral antagonists at mu opioid receptor (MOR): possible role of basal receptor signaling in narcotic dependence". Journal of Neurochemistry. 77 (3): 1590–600. doi: 10.1046/j.1471-4159.2001.00362.x . PMID   11413242. S2CID   10026688.
  8. 1 2 Khilnani G, Khilnani AK (2011). "Inverse agonism and its therapeutic significance". Indian J Pharmacol. 43 (5): 492–501. doi:10.4103/0253-7613.84947. PMC   3195115 . PMID   22021988.
  9. 1 2 3 Prather, Paul L. (2004-01-05). "Inverse agonists: tools to reveal ligand-specific conformations of G protein-coupled receptors". Science's STKE: Signal Transduction Knowledge Environment. 2004 (215): pe1. doi:10.1126/stke.2152004pe1. ISSN   1525-8882. PMID   14722344. S2CID   22336235.
  10. 1 2 Hirayama, Shigeto; Fujii, Hideaki (2020). "δ Opioid Receptor Inverse Agonists and their In Vivo Pharmacological Effects". Current Topics in Medicinal Chemistry. 20 (31): 2889–2902. doi:10.2174/1568026620666200402115654. ISSN   1873-4294. PMID   32238139. S2CID   214767114.
  11. Berg, Kelly A.; Clarke, William P. (2018-10-01). "Making Sense of Pharmacology: Inverse Agonism and Functional Selectivity". The International Journal of Neuropsychopharmacology. 21 (10): 962–977. doi:10.1093/ijnp/pyy071. ISSN   1469-5111. PMC   6165953 . PMID   30085126.
  12. 1 2 3 4 Strange, Philip G. (February 2002). "Mechanisms of inverse agonism at G-protein-coupled receptors". Trends in Pharmacological Sciences. 23 (2): 89–95. doi:10.1016/s0165-6147(02)01993-4. ISSN   0165-6147. PMID   11830266.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.