Tag: Neurotransmitter

What is a Serotonin Transporter?

Published on by Andrew Marshall9 Comments

Introduction

The serotonin transporter (SERT or 5-HTT) also known as the sodium-dependent serotonin transporter and solute carrier family 6 menmber 4 is a protein that in humans is encoded by the SLC6A4 gene. SERT is a type of monoamine transporter protein that transports the neurotransmitter serotonin from the synaptic cleft back to the presynaptic neuron, in a process known as serotonin reuptake.

This transport of serotonin by the SERT protein terminates the action of serotonin and recycles it in a sodium-dependent manner. Many antidepressant medications of the SSRI and tricyclic antidepressant classes work by binding to SERT and thus reducing serotonin reuptake. It is a member of the sodium:neurotransmitter symporter family. A repeat length polymorphism in the promoter of this gene has been shown to affect the rate of serotonin uptake and may play a role in sudden infant death syndrome, aggressive behaviour in Alzheimer disease patients, post-traumatic stress disorder and depression-susceptibility in people experiencing emotional trauma.

Mechanism of Action

Serotonin-reuptake transporters are dependent on both the concentration of potassium ion in the cytoplasm and the concentrations of sodium and chloride ions in the extracellular fluid. In order to function properly the serotonin transporter requires the membrane potential created by the sodium-potassium adenosine triphosphatase.

The serotonin transporter first binds a sodium ion, followed by the serotonin, and then a chloride ion; it is then allowed, thanks to the membrane potential, to flip inside the cell freeing all the elements previously bound. Right after the release of the serotonin in the cytoplasm a potassium ion binds to the transporter which is now able to flip back out returning to its active state.

Function

The serotonin transporter removes serotonin from the synaptic cleft back into the synaptic boutons. Thus, it terminates the effects of serotonin and simultaneously enables its reuse by the presynaptic neuron.

Neurons communicate by using chemical messengers like serotonin between cells. The transporter protein, by recycling serotonin, regulates its concentration in a gap, or synapse, and thus its effects on a receiving neuron’s receptors.

Medical studies have shown that changes in serotonin transporter metabolism appear to be associated with many different phenomena, including alcoholism, clinical depression, obsessive–compulsive disorder (OCD), romantic love, hypertension and generalized social phobia.

The serotonin transporter is also present in platelets; there, serotonin functions as a vasoconstrictive substance. It also serves as a signalling molecule to induce platelet aggregation.

Pharmacology

In 1995 and 1996, scientists in Europe had identified the polymorphism 5-HTTLPR, a serotonin-transporter in the gene SLC6A4. In December 1996, a group of researchers led by D.A. Collier of the Institute of Psychiatry, Psychology and Neuroscience, published their findings in Molecular Psychiatry, that, “5-HTTLPR-dependent variation in functional 5-HTT expression is a potential genetic susceptibility factor for affective disorders.”

SERT spans the plasma membrane 12 times. It belongs to the NE, DA, SERT monoamine transporter family. Transporters are important sites for agents that treat psychiatric disorders. Drugs that reduce the binding of serotonin to transporters (serotonin reuptake inhibitors, or SRIs) are used to treat mental disorders. The selective serotonin reuptake inhibitor (SSRI) fluoxetine and the tricyclic antidepressant (TCA) clomipramine are examples of serotonin reuptake inhibitors.

Following the elucidation of structures of the homologous bacterial transporter, LeuT, co-crystallised with tricyclic antidepressants in the vestibule leading from the extracellular space to the central substrate site it was inferred that this binding site did also represent the binding site relevant for antidepressant binding in SERT. However, studies on SERT showed that tricyclic antidepressants and selective serotonin reuptake inhibitors bind to the central binding site overlapping the substrate binding site. The Drosophila dopamine transporter, which displays a pharmacology similar to SERT, was crystallised with tricyclic antidepressants and confirmed the earlier finding that the substrate binding site is also the antidepressant binding site.

Ligands

  • DASB, also known as 3-amino-4-(2-dimethylaminomethylphenylsulfanyl)-benzonitrile, is a compound that binds to the serotonin transporter.
  • compound 4b: Ki = 17 pM; 710-fold and 11,100-fold selective over DAT and NET
  • compound (+)-12a: Ki = 180 pM at hSERT; >1000-fold selective over hDAT, hNET, 5-HT1A, and 5-HT6. Isosteres
  • 3-cis-(3-Aminocyclopentyl)indole 8a: Ki = 220 pM
  • allosteric modulator: 3′-Methoxy-8-methyl-spiro{8-azabicyclo[3.2.1]octane-3,5′(4′H)-isoxazole} (compound 7a)
  • allosteric modulator: p-Trifluoromethyl-methcathinone

Genetics

The gene that encodes the serotonin transporter is called solute carrier family 6 (neurotransmitter transporter, serotonin), member 4 (SLC6A4, refer to Solute carrier family). In humans the gene is found on chromosome 17 on location 17q11.1–q12.

Mutations associated with the gene may result in changes in serotonin transporter function, and experiments with mice have identified more than 50 different phenotypic changes as a result of genetic variation. These phenotypic changes may, e.g., be increased anxiety and gut dysfunction. Some of the human genetic variations associated with the gene are:

  • Length variation in the serotonin-transporter-gene-linked polymorphic region (5-HTTLPR)
  • rs25531 — a single nucleotide polymorphism (SNP) in the 5-HTTLPR
  • rs25532 — another SNP in the 5-HTTLPR
  • STin2 — a variable number of tandem repeats (VNTR) in the functional intron 2
  • G56A on the second exon
  • I425V on the ninth exon

Length Variation in 5-HTTLPR

Refer to 5-HTTLPR.

According to a 1996 article in The Journal of Neurochemistry, the promoter region of the SLC6A4 gene contains a polymorphism with “short” and “long” repeats in a region: 5-HTT-linked polymorphic region (5-HTTLPR or SERTPR). The short variation has 14 repeats of a sequence while the long variation has 16 repeats. A second 1996 article stated that the short variation leads to less transcription for SLC6A4, and it has been found that it can partly account for anxiety-related personality traits. This polymorphism has been extensively investigated in over 300 scientific studies (as of 2006). The 5-HTTLPR polymorphism may be subdivided further: One study published in 2000 found 14 allelic variants (14-A, 14-B, 14-C, 14-D, 15, 16-A, 16-B, 16-C, 16-D, 16-E, 16-F, 19, 20 and 22) in a group of around 200 Japanese and Caucasian people.

In addition to altering the expression of SERT protein and concentrations of extracellular serotonin in the brain, the 5-HTTLPR variation is associated with changes in brain structure. One 2005 study found less grey matter in perigenual anterior cingulate cortex and amygdala for short allele carriers of the 5-HTTLPR polymorphism compared to subjects with the long/long genotype.

In contrast, a 2008 meta-analysis found no significant overall association between the 5-HTTLPR polymorphism and autism. A hypothesized gene–environment interaction between the short/short allele of the 5-HTTLPR and life stress as predictor for major depression has suffered a similar fate: after an influential initial report in 2003 there were mixed results in replication in 2008, and a 2009 meta-analysis was negative.

rs25532

rs25532 is a SNP (C>T) close to the site of 5-HTTLPR. It has been examined in connection with obsessive compulsive disorder (OCD).

I425V

I425V is a rare mutation on the ninth exon. In 2003, researchers from Japan and the US reported that they had found this genetic variation in unrelated families with OCD, and have found that it leads to faulty transporter function and regulation. A second variant in the same gene of some patients with this mutation suggests a genetic “double hit”, resulting in greater biochemical effects and more severe symptoms.

VNTR in STin2

Another noncoding polymorphism is a VNTR in the second intron (STin2). In a 2005 study, it was found with three alleles: 9, 10 and 12 repeats. A meta-analysis has found that the 12 repeat allele of the STin2 VNTR polymorphism had some minor (with odds ratio 1.24), but statistically significant, association with schizophrenia. A 2008 meta-analysis found no significant overall association between the STin2 VNTR polymorphism and autism. Furthermore, a 2003 meta-analysis of affective disorders, major depressive disorder and bipolar disorder, found a minor association to the intron 2 VNTR polymorphism, but the results of the meta-analysis were dependent upon a large effect from one individual study.

The polymorphism has also been related to personality traits with a 2008 Russian study finding individuals with the STin2.10 allele having lower neuroticism scores as measured with the Eysenck Personality Inventory.

Neuroimaging

The distribution of the serotonin transporter in the brain may be imaged with positron emission tomography using radioligands called DASB and DAPP; the first such studies on the human brain were reported in 2000. DASB and DAPP are not the only radioligands for the serotonin transporter. There are numerous others, with the most popular probably being the β-CIT radioligand with an iodine-123 isotope that is used for brain scanning with single-photon emission computed tomography (SPECT) according to a 1993 article in the Journal of Neural Transmission. The radioligands were used in 2006 to examine whether variables such as age, gender or genotype are associated with differential serotonin transporter binding. Healthy subjects that have a high score of neuroticism—a personality trait in the Revised NEO Personality Inventory—were found to have more serotonin transporter binding in the thalamus in 2007.

Neuroimaging and Genetics

Studies on the serotonin transporter have combined neuroimaging and genetics methods, e.g., a voxel-based morphometry study found less grey matter in perigenual anterior cingulate cortex and amygdala for short allele carriers of the 5-HTTLPR polymorphism compared to subjects with the long/long genotype.

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What is a Monoamine Reuptake Inhibitor?

Published on by Andrew Marshall5 Comments

Introduction

A monoamine reuptake inhibitor (MRI) is a drug that acts as a reuptake inhibitor of one or more of the three major monoamine neurotransmitters serotonin, norepinephrine, and dopamine by blocking the action of one or more of the respective monoamine transporters (MATs), which include the serotonin transporter (SERT), norepinephrine transporter (NET), and dopamine transporter (DAT). This in turn results in an increase in the synaptic concentrations of one or more of these neurotransmitters and therefore an increase in monoaminergic neurotransmission.

Uses

The majority of currently approved antidepressants act predominantly or exclusively as MRIs, including the selective serotonin reuptake inhibitors (SSRIs), serotonin–norepinephrine reuptake inhibitors (SNRIs), and almost all of the tricyclic antidepressants (TCAs). Many psychostimulants used either in the treatment of ADHD or as appetite suppressants in the treatment of obesity also behave as MRIs, although notably amphetamine (and methamphetamine), which do act to some extent as monoamine reuptake inhibitors, exerts their effects primarily as releasing agents. Additionally, psychostimulants acting as MRIs that affect dopamine such as cocaine and methylphenidate are often abused as recreational drugs. As a result, many of them have become controlled substances, which in turn has resulted in the clandestine synthesis of a vast array of designer drugs for the purpose of bypassing drug laws; a prime example of such is the mixed monoamine reuptake inhibitor and releasing agent mephedrone.

Types of MRIs

There are a variety of different kinds of MRIs, of which include the following:

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What is a Reuptake Inhibitor?

Published on by Andrew Marshall4 Comments

Introduction

A reuptake inhibitor (RI) is a type of drug known as a reuptake modulator that inhibits the plasmalemmal transporter-mediated reuptake of a neurotransmitter from the synapse into the pre-synaptic neuron. This leads to an increase in extracellular concentrations of the neurotransmitter and an increase in neurotransmission. Various drugs exert their psychological and physiological effects through reuptake inhibition, including many antidepressants and psychostimulants.

Most known reuptake inhibitors affect the monoamine neurotransmitters serotonin, norepinephrine (and epinephrine), and dopamine. However, there are also a number of pharmaceuticals and research chemicals that act as reuptake inhibitors for other neurotransmitters such as glutamate, γ-aminobutyric acid (GABA), glycine, adenosine, choline (the precursor of acetylcholine), and the endocannabinoids, among others.

Mechanism of Action

Active Site Transporter Substrates

Standard reuptake inhibitors are believed to act simply as competitive substrates that work by binding directly to the plasmalemma transporter of the neurotransmitter in question. They occupy the transporter in place of the respective neurotransmitter and competitively block it from being transported from the nerve terminal or synapse into the pre-synaptic neuron. With high enough doses, occupation becomes as much as 80–90%. At this level of inhibition, the transporter will be considerably less efficient at removing excess neurotransmitter from the synapse and this causes a substantial increase in the extracellular concentrations of the neurotransmitter and therefore an increase in overall neurotransmission.

Allosteric Site Transporter Substrates

Alternatively, some reuptake inhibitors bind to allosteric sites and inhibit reuptake indirectly and noncompetitively.

Phencyclidine and related drugs such as benocyclidine, tenocyclidine, ketamine, and dizocilpine (MK-801), have been shown to inhibit the reuptake of the monoamine neurotransmitters. They appear to exert their reuptake inhibition by binding to vaguely characterised allosteric sites on each of the respective monoamine transporters. Benztropine, mazindol, and vanoxerine also bind to these sites and have similar properties. In addition to their high affinity for the main site of the monoamine transporters, several competitive transporter substrates such as cocaine and indatraline have lower affinity for these allosteric sites as well.

A few of the selective serotonin reuptake inhibitors (SSRIs) such as the dextro-enantiomer of citalopram appear to be allosteric reuptake inhibitors of serotonin. Instead of binding to the active site on the serotonin transporter, they bind to an allosteric site, which exerts its effects by causing conformational changes in the transporter protein and thereby modulating the affinity of substrates for the active site. As a result, escitalopram has been marketed as an allosteric serotonin reuptake inhibitor. Notably, this allosteric site may be directly related to the above-mentioned PCP binding sites.

Vesicular Transporter Substrates

A second type of reuptake inhibition affects vesicular transport, and blocks the intracellular repackaging of neurotransmitters into cytoplasmic vesicles. In contrast to plasmalemmal reuptake inhibitors, vesicular reuptake inhibitors do not increase the synaptic concentrations of a neurotransmitter, only the cytoplasmic concentrations; unless, that is, they also act as plasmalemmal transporter reversers via phosphorylation of the transporter protein, also known as a releasing agent. Pure vesicular reuptake inhibitors tend to actually lower synaptic neurotransmitter concentrations, as blocking the repackaging of, and storage of the neurotransmitter in question leaves them vulnerable to degradation via enzymes such as monoamine oxidase (MAO) that exist in the cytoplasm. With vesicular transport blocked, neurotransmitter stores quickly become depleted.

Reserpine (Serpasil) is an irreversible inhibitor of the vesicular monoamine transporter 2 (VMAT2), and is a prototypical example of a vesicular reuptake inhibitor.

Indirect Unknown Mechanism

Two of the primary active constituents of the medicinal herb Hypericum perforatum (St. John’s Wort) are hyperforin and adhyperforin. Hyperforin and adhyperforin are wide-spectrum inhibitors of the reuptake of serotonin, norepinephrine, dopamine, glutamate, GABA, glycine, and choline, and they exert these effects by binding to and activating the transient receptor potential cation channel TRPC6. Activation of TRPC6 induces the entry of calcium (Ca2+) and sodium (Na+) into the cell, which causes the effect through unknown mechanism.

Types

Typical

  • Amino acid reuptake inhibitor:
    • Excitatory amino acid reuptake inhibitor (or glutamate-aspartate reuptake inhibitor)
    • GABA reuptake inhibitor
    • Glycine reuptake inhibitor
  • Monoamine reuptake inhibitor:
    • Dopamine reuptake inhibitor
    • Norepinephrine reuptake inhibitor
    • Serotonin reuptake inhibitor
    • Serotonin-norepinephrine reuptake inhibitor
    • Norepinephrine-dopamine reuptake inhibitor
    • Serotonin-dopamine reuptake inhibitor
    • Serotonin-norepinephrine-dopamine reuptake inhibitor
  • Miscellaneous:
    • Adenosine reuptake inhibitor
    • Endocannabinoid reuptake inhibitor

Atypical

  • TRPC6 activators (wide-spectrum reuptake inhibitors) – hyperforin, adhyperforin

Plasmalemmal

  • Choline reuptake inhibitor – hemicholinium-3, triethylcholine

Vesicular

  • Vesicular acetylcholine transporter (VAChT) inhibitor – vesamicol
  • Vesicular monoamine transporter (VMAT) inhibitor – reserpine, tetrabenazine

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What is a Serotonin-Dopamine Reuptake Inhibitor?

Published on by Andrew Marshall2 Comments

Introduction

A serotonin–dopamine reuptake inhibitor (SDRI) is a type of drug which acts as a reuptake inhibitor of the monoamine neurotransmitters serotonin and dopamine by blocking the actions of the serotonin transporter (SERT) and dopamine transporter (DAT), respectively. This in turn leads to increased extracellular concentrations of serotonin and dopamine, and, therefore, an increase in serotonergic and dopaminergic neurotransmission.

A closely related type of drug is a serotonin–dopamine releasing agent (SDRA).

Comparison to SNDRIs

Relative to serotonin–norepinephrine–dopamine reuptake inhibitors (SNDRIs), which also inhibit the reuptake of norepinephrine in addition to serotonin and dopamine, SDRIs might be expected to have a reduced incidence of certain side effects, namely insomnia, appetite loss, anxiety, and heart rate and blood pressure changes.

Examples of SDRIs

Unlike the case of other combination monoamine reuptake inhibitors such as serotonin–norepinephrine reuptake inhibitors (SNRIs) and norepinephrine–dopamine reuptake inhibitors (NDRIs), on account of the very similar chemical structures of their substrates, it is exceptionally difficult to tease apart affinity for the DAT from the norepinephrine transporter (NET) and inhibit the reuptake of dopamine alone. As a result, selective dopamine reuptake inhibitors (DRIs) are rare, and comparably, SDRIs are even more so.

Pharmaceutical Drugs

Medifoxamine (Cledial, Gerdaxyl) is an antidepressant that appears to act as an SDRI as well as a 5-HT2 receptor antagonist. Sibutramine (Reductil, Meridia, Siredia, Sibutrex) is a withdrawn anorectic that itself as a molecule in vitro is an SNDRI but preferentially an SDRI, with 18.3- and 5.8-fold preference for inhibiting the reuptake of serotonin and dopamine over norepinephrine, respectively. However, the metabolites of sibutramine are substantially more potent and possess different ratios of monoamine reuptake inhibition in comparison, and sibutramine appears to be acting in vivo mainly as a prodrug to them; accordingly, it was found to act as an SNRI (73% and 54% for norepinephrine and serotonin reuptake inhibition, respectively) in human volunteers with only very weak inhibition of dopamine reuptake (16%).

Sertraline

Sertraline (Zoloft) is a selective serotonin reuptake inhibitor (SSRI), but, uniquely among most antidepressants, it shows relatively high (nanomolar) affinity for the DAT as well. As such, it has been suggested that clinically it may weakly inhibit the reuptake of dopamine, particularly at high dosages. For this reason, sertraline has sometimes been described as an SDRI. This is relevant as dopamine is thought to be involved in the pathophysiology of depression, and increased dopaminergic signaling by sertraline in addition to serotonin may have additional benefits against depression.

Tatsumi et al. (1997) found Ki values of sertraline at the SERT, DAT, and NET of 0.29, 25, and 420 nM, respectively. The selectivity of sertraline for the SERT over the DAT was 86-fold. In any case, of the wide assortment of antidepressants assessed in the study, sertraline showed the highest affinity of them all for the DAT, even higher than the norepinephrine–dopamine reuptake inhibitors (NDRIs) nomifensine (Ki = 56 nM) and bupropion (Ki = 520 nM). Sertraline is also said to have similar affinity for the DAT as the NDRI methylphenidate. It is notable that tametraline (CP-24,441), a very close analogue of sertraline and the compound from which sertraline was originally derived, is an NDRI that was never marketed.

Single doses of 50 to 200 mg sertraline have been found to result in peak plasma concentrations of 20 to 55 ng/mL (65–180 nM), while chronic treatment with 200 mg/day sertraline, the maximum recommended dosage, has been found to result in maximal plasma levels of 118 to 166 ng/mL (385–542 nM). However, sertraline is highly protein-bound in plasma, with a bound fraction of 98.5%. Hence, only 1.5% is free and theoretically bioactive. Based on this percentage, free concentrations of sertraline would be 2.49 ng/mL (8.13 nM) at the very most, which is only about one-third of the Ki value that Tatsumi et al. found with sertraline at the DAT. A very high dosage of sertraline of 400 mg/day has been found to produce peak plasma concentrations of about 250 ng/mL (816 nM). This can be estimated to result in a free concentration of 3.75 ng/mL (12.2 nM), which is still only about half of the Ki of sertraline for the DAT.

As such, it seems unlikely that sertraline would produce much inhibition of dopamine reuptake even at clinically used dosages well in excess of the recommended maximum clinical dosage. This is in accordance with its 86-fold selectivity for the SERT over the DAT and hence the fact that nearly 100-fold higher levels of sertraline would be necessary to also inhibit dopamine reuptake. In accordance, while sertraline has very low abuse potential and may even be aversive at clinical dosages, a case report of sertraline abuse described dopaminergic-like effects such as euphoria, mental overactivity, and hallucinations only at a dosage 56 times the normal maximum and 224 times the normal minimum. For these reasons, significant inhibition of dopamine reuptake by sertraline at clinical dosages is controversial, and occupation by sertraline of the DAT is thought by many experts to not be clinically relevant.

Research Chemicals

Two SDRIs that are known in research at present are RTI-83 and UWA-101, though other related compounds are also known. Based on its chemical structure, UWA-101 may actually also possess some activity as a releasing agent, and if so, unlike RTI-83, it would not be an SDRI in the purest sense and would also be an SDRA. Manning et al. presented two high-affinity MAT-ligands with good binding selectivity for SERT and DAT, namely the 4-indolyl and 1-naphthyl arylalkylamines ent-16b (Ki 0.82, 3.8, 4840 nM for SERT, DAT, NET) and ent-13b respectively. AN-788 (NSD-788) is another SDRI, and has been under development for the treatment of depressive and anxiety disorders.

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What is Adrenergic?

Published on by Andrew Marshall7 Comments

Introduction

Adrenergic means “working on adrenaline (epinephrine) or noradrenaline (norepinephrine)” (or on their receptors). When not further qualified, it is usually used in the sense of enhancing or mimicking the effects of epinephrine and norepinephrine in the body.

Outline

Adrenergic nervous system, a part of the autonomic nervous system that uses epinephrine or norepinephrine as its neurotransmitter

Regarding proteins:

  • Adrenergic receptor, a receptor type for epinephrine and norepinephrine; subtypes include α1, α2, β1, β2, and β3 receptors
  • Adrenergic transporter (norepinephrine transporter), a protein transporting norepinephrine from the synaptic cleft into nerve cells

Regarding pharmaceutical drugs:

  • Adrenergic receptor agonist, a type of drug activating one or more subtypes of adrenergic receptors.
  • This includes drugs regulating blood pressure and antiasthmatic drugs.
  • Adrenergic receptor antagonist, a type of drug blocking one or more subtypes of adrenergic receptors.
  • This mainly includes drugs lowering blood pressure.
  • Adrenergic reuptake inhibitor, a type of drug blocking the norepinephrine transporter.
  • This includes antidepressants and drugs against ADHD.

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What is Dopaminergic?

Published on by Andrew Marshall4 Comments

Introduction

Dopaminergic means “related to dopamine” (literally, “working on dopamine”), dopamine being a common neurotransmitter. Dopaminergic substances or actions increase dopamine-related activity in the brain.

Outline

Dopaminergic brain pathways facilitate dopamine-related activity. For example, certain proteins such as the dopamine transporter (DAT), vesicular monoamine transporter 2 (VMAT2), and dopamine receptors can be classified as dopaminergic, and neurons that synthesize or contain dopamine and synapses with dopamine receptors in them may also be labelled as dopaminergic.

Enzymes that regulate the biosynthesis or metabolism of dopamine such as aromatic L-amino acid decarboxylase or DOPA decarboxylase, monoamine oxidase (MAO), and catechol O-methyl transferase (COMT) may be referred to as dopaminergic as well. Also, any endogenous or exogenous chemical substance that acts to affect dopamine receptors or dopamine release through indirect actions (for example, on neurons that synapse onto neurons that release dopamine or express dopamine receptors) can also be said to have dopaminergic effects, two prominent examples being opioids, which enhance dopamine release indirectly in the reward pathways, and some substituted amphetamines, which enhance dopamine release directly by binding to and inhibiting VMAT2.

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What is a Norepinephrine-Dopamine Reuptake Inhibitor?

Published on by Andrew Marshall9 Comments

Introduction

A norepinephrine–dopamine reuptake inhibitor (NDRI) is a drug used for the treatment of clinical depression, attention deficit hyperactivity disorder (ADHD), narcolepsy, and the management of Parkinson’s disease. The drug acts as a reuptake inhibitor for the neurotransmitters norepinephrine and dopamine by blocking the action of the norepinephrine transporter (NET) and the dopamine transporter (DAT), respectively. This in turn leads to increased extracellular concentrations of both norepinephrine and dopamine and, therefore, an increase in adrenergic and dopaminergic neurotransmission.

A closely related type of drug is a norepinephrine–dopamine releasing agent (NDRA).

List of NDRIs

The section only lists compounds that are selective for NET and DAT relative to the serotonin transporter (SERT). For a list of compounds that inhibit reuptake at all three transporters, see serotonin–norepinephrine–dopamine reuptake inhibitor.

Many NDRIs exist, including the following:

  • Amineptine (Survector, Maneon, Directim)
  • Bupropion (Wellbutrin, Zyban)
  • Desoxypipradrol (2-DPMP)
  • Dexmethylphenidate (Focalin)
  • Difemetorex (Cleofil)
  • Diphenylprolinol (D2PM)
  • Ethylphenidate
  • Fencamfamine (Glucoenergan, Reactivan)
  • Fencamine (Altimina, Sicoclor)
  • Lefetamine (Santenol)
  • Methylenedioxypyrovalerone (MDPV)
  • Methylphenidate (Ritalin, Concerta, Metadate, Methylin)
  • Nomifensine (Merital)
  • O-2172
  • Phenylpiracetam (Phenotropil, Carphedon)
  • Pipradrol (Meretran)
  • Prolintane (Promotil, Katovit)
  • Pyrovalerone (Centroton, Thymergix)
  • Solriamfetol (Sunosi)
  • Tametraline (CP-24,411)
  • WY-46824

Amphetamine and many of its immediate derivatives (i.e., the substituted amphetamines) are also both non-competitive and competitive inhibitors of the dopamine transporter (DAT), norepinephrine transporter (NET), and serotonin transporter (SERT) proteins. Amphetamine itself has comparatively low affinity for SERT relative to DAT and NET. Consequently, amphetamine is usually classified as an NDRI instead of an SNDRI. However, the substituted amphetamines have a very diverse effects profile, and many of them have significant inhibiting effects on the SERT.

Amphetamine and many of the other substituted amphetamines are inhibitors of VMAT2 and potent agonists of the trace amine-associated receptor 1 (TAAR1); agonism of TAAR1 triggers phosphorylation events that result in both non-competitive reuptake inhibition and reversed transport direction of monoamine transporter proteins. As a result, monoamines flow out of the cell and into the synaptic cleft. Thus, amphetamine and its derivatives have a pharmacological profile that is much different than classical NDRIs, but analogous to trace amines.

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What is Norepinephrine?

Published on by Andrew Marshall34 Comments

Introduction

Norepinephrine (NE), also called noradrenaline (NA) or noradrenalin, is an organic chemical in the catecholamine family that functions in the brain and body as both a hormone and neurotransmitter. The name “noradrenaline” (from Latin ad, “near”, and ren, “kidney”) is more commonly used in the United Kingdom, whereas “norepinephrine” (from Ancient Greek ἐπῐ́ (epí), “upon”, and νεφρός (nephrós), “kidney”) is usually preferred in the United States. “Norepinephrine” is also the international nonproprietary name given to the drug. Regardless of which name is used for the substance itself, parts of the body that produce or are affected by it are referred to as noradrenergic.

The general function of norepinephrine is to mobilise the brain and body for action. Norepinephrine release is lowest during sleep, rises during wakefulness, and reaches much higher levels during situations of stress or danger, in the so-called fight-or-flight response. In the brain, norepinephrine increases arousal and alertness, promotes vigilance, enhances formation and retrieval of memory, and focuses attention; it also increases restlessness and anxiety. In the rest of the body, norepinephrine increases heart rate and blood pressure, triggers the release of glucose from energy stores, increases blood flow to skeletal muscle, reduces blood flow to the gastrointestinal system, and inhibits voiding of the bladder and gastrointestinal motility.

In the brain, noradrenaline is produced in nuclei that are small yet exert powerful effects on other brain areas. The most important of these nuclei is the locus coeruleus, located in the pons. Outside the brain, norepinephrine is used as a neurotransmitter by sympathetic ganglia located near the spinal cord or in the abdomen, as well as Merkel cells located in the skin. It is also released directly into the bloodstream by the adrenal glands. Regardless of how and where it is released, norepinephrine acts on target cells by binding to and activating adrenergic receptors located on the cell surface.

A variety of medically important drugs work by altering the actions of noradrenaline systems. Noradrenaline itself is widely used as an injectable drug for the treatment of critically low blood pressure. Stimulants often increase, enhance, or otherwise act as agonists of norepinephrine. Drugs such as cocaine and methylphenidate act as reuptake inhibitors of norepinephrine, as do some antidepressants, such as those in the SNRI class. One of the more notable drugs in the stimulant class is amphetamine, which acts as a dopamine and norepinephrine analog, reuptake inhibitor, as well as an agent that increases the amount of global catecholamine signaling throughout the nervous system by reversing transporters in the synapses. Beta blockers, which counter some of the effects of noradrenaline by blocking their receptors, are frequently used to treat glaucoma, migraine, and a range of cardiovascular problems. Alpha blockers, which counter a different set of noradrenaline effects, are used to treat several cardiovascular and psychiatric conditions. Alpha-2 agonists often have a sedating effect and are commonly used as anesthesia enhancers in surgery, as well as in treatment of drug or alcohol dependence. For reasons that are still unclear, some Alpha-2 drugs, such as guanfacine, have also been shown to be effective in the treatment of anxiety disorders and ADHD. Many important psychiatric drugs exert strong effects on noradrenaline systems in the brain, resulting in side-effects that may be helpful or harmful.

Refer to Norepinephrine (Medication).

Brief History

Early in the twentieth century Walter Cannon, who had popularized the idea of a sympathoadrenal system preparing the body for fight and flight, and his colleague Arturo Rosenblueth developed a theory of two sympathins, sympathin E (excitatory) and sympathin I (inhibitory), responsible for these actions. The Belgian pharmacologist Zénon Bacq as well as Canadian and US pharmacologists between 1934 and 1938 suggested that noradrenaline might be a sympathetic transmitter. In 1939, Hermann Blaschko and Peter Holtz independently identified the biosynthetic mechanism for norepinephrine in the vertebrate body. In 1945 Ulf von Euler published the first of a series of papers that established the role of norepinephrine as a neurotransmitter. He demonstrated the presence of norepinephrine in sympathetically innervated tissues and brain, and adduced evidence that it is the sympathin of Cannon and Rosenblueth.

Stanley Peart was the first to demonstrate the release of noradrenaline after the stimulation of sympathetic nerves.

Structure

Norepinephrine is a catecholamine and a phenethylamine. Its structure differs from that of epinephrine only in that epinephrine has a methyl group attached to its nitrogen, whereas the methyl group is replaced by a hydrogen atom in norepinephrine. The prefix nor- is derived as an abbreviation of the word “normal”, used to indicate a demethylated compound. Norepinephrine consists of a catechol moiety (a benzene ring with two adjoining hydroxyl groups in the meta-para position), and an ethylamine side chain consisting of a hydroxyl group bonded in the benzylic position.

Biochemical Mechanisms

Biosynthesis

Norepinephrine is synthesized from the amino acid tyrosine by a series of enzymatic steps in the adrenal medulla and postganglionic neurons of the sympathetic nervous system. While the conversion of tyrosine to dopamine occurs predominantly in the cytoplasm, the conversion of dopamine to norepinephrine by dopamine β-monooxygenase occurs predominantly inside neurotransmitter vesicles. The metabolic pathway is:

Phenylalanine → Tyrosine → L-DOPA → Dopamine → Norepinephrine

Thus the direct precursor of norepinephrine is dopamine, which is synthesized indirectly from the essential amino acid phenylalanine or the non-essential amino acid tyrosine. These amino acids are found in nearly every protein and, as such, are provided by ingestion of protein-containing food, with tyrosine being the most common.

Phenylalanine is converted into tyrosine by the enzyme phenylalanine hydroxylase, with molecular oxygen (O2) and tetrahydrobiopterin as cofactors. Tyrosine is converted into L-DOPA by the enzyme tyrosine hydroxylase, with tetrahydrobiopterin, O2, and probably ferrous iron (Fe2+) as cofactors. Conversion of tyrosine to L-DOPA is inhibited by Metyrosine, a tyrosine analog. L-DOPA is converted into dopamine by the enzyme aromatic L-amino acid decarboxylase (also known as DOPA decarboxylase), with pyridoxal phosphate as a cofactor. Dopamine is then converted into norepinephrine by the enzyme dopamine β-monooxygenase (formerly known as dopamine β-hydroxylase), with O2 and ascorbic acid as cofactors.

Norepinephrine itself can further be converted into epinephrine by the enzyme phenylethanolamine N-methyltransferase with S-adenosyl-L-methionine as cofactor.

Degradation

In mammals, norepinephrine is rapidly degraded to various metabolites. The initial step in the breakdown can be catalysed by either of the enzymes monoamine oxidase (mainly monoamine oxidase A) or COMT. From there, the breakdown can proceed by a variety of pathways. The principal end products are either Vanillylmandelic acid or a conjugated form of MHPG, both of which are thought to be biologically inactive and are excreted in the urine.

Functions

Cellular Effects

Like many other biologically active substances, norepinephrine exerts its effects by binding to and activating receptors located on the surface of cells. Two broad families of norepinephrine receptors have been identified, known as alpha and beta adrenergic receptors.

  • Alpha receptors are divided into subtypes α1 and α2; and
  • Beta receptors into subtypes β1, β2, and β3.

All of these function as G protein-coupled receptors, meaning that they exert their effects via a complex second messenger system. Alpha-2 receptors usually have inhibitory effects, but many are located pre-synaptically (i.e. on the surface of the cells that release norepinephrine), so the net effect of alpha-2 activation is often a decrease in the amount of norepinephrine released. Alpha-1 receptors and all three types of beta receptors usually have excitatory effects.

Storage, Release, and Reuptake

Inside the brain norepinephrine functions as a neurotransmitter, and is controlled by a set of mechanisms common to all monoamine neurotransmitters. After synthesis, norepinephrine is transported from the cytosol into synaptic vesicles by the vesicular monoamine transporter (VMAT). VMAT can be inhibited by Reserpine causing a decrease in neurotransmitter stores. Norepinephrine is stored in these vesicles until it is ejected into the synaptic cleft, typically after an action potential causes the vesicles to release their contents directly into the synaptic cleft through a process called exocytosis.

Once in the synapse, norepinephrine binds to and activates receptors. After an action potential, the norepinephrine molecules quickly become unbound from their receptors. They are then absorbed back into the presynaptic cell, via reuptake mediated primarily by the norepinephrine transporter (NET). Once back in the cytosol, norepinephrine can either be broken down by monoamine oxidase or repackaged into vesicles by VMAT, making it available for future release.

Sympathetic Nervous System

Norepinephrine is the main neurotransmitter used by the sympathetic nervous system, which consists of about two dozen sympathetic chain ganglia located next to the spinal cord, plus a set of prevertebral ganglia located in the chest and abdomen. These sympathetic ganglia are connected to numerous organs, including the eyes, salivary glands, heart, lungs, liver, gallbladder, stomach, intestines, kidneys, urinary bladder, reproductive organs, muscles, skin, and adrenal glands. Sympathetic activation of the adrenal glands causes the part called the adrenal medulla to release norepinephrine (as well as epinephrine) into the bloodstream, from which, functioning as a hormone, it gains further access to a wide variety of tissues.

Broadly speaking, the effect of norepinephrine on each target organ is to modify its state in a way that makes it more conducive to active body movement, often at a cost of increased energy use and increased wear and tear. This can be contrasted with the acetylcholine-mediated effects of the parasympathetic nervous system, which modifies most of the same organs into a state more conducive to rest, recovery, and digestion of food, and usually less costly in terms of energy expenditure.

The sympathetic effects of norepinephrine include:

  • In the eyes, an increase in production of tears, making the eyes more moist,[18] and pupil dilation through contraction of the iris dilator.
  • In the heart, an increase in the amount of blood pumped.
  • In brown adipose tissue, an increase in calories burned to generate body heat (thermogenesis).
  • Multiple effects on the immune system. The sympathetic nervous system is the primary path of interaction between the immune system and the brain, and several components receive sympathetic inputs, including the thymus, spleen, and lymph nodes. However the effects are complex, with some immune processes activated while others are inhibited.
  • In the arteries, constriction of blood vessels, causing an increase in blood pressure.
  • In the kidneys, release of renin and retention of sodium in the bloodstream.
  • In the liver, an increase in production of glucose, either by glycogenolysis after a meal or by gluconeogenesis when food has not recently been consumed. Glucose is the body’s main energy source in most conditions.
  • In the pancreas, increased release of glucagon, a hormone whose main effect is to increase the production of glucose by the liver.
  • In skeletal muscles, an increase in glucose uptake.
  • In adipose tissue (i.e., fat cells), an increase in lipolysis, that is, conversion of fat to substances that can be used directly as energy sources by muscles and other tissues.
  • In the stomach and intestines, a reduction in digestive activity. This results from a generally inhibitory effect of norepinephrine on the enteric nervous system, causing decreases in gastrointestinal mobility, blood flow, and secretion of digestive substances.

Noradrenaline and ATP are sympathetic co-transmitters. It is found that the endocannabinoid anandamide and the cannabinoid WIN 55,212-2 can modify the overall response to sympathetic nerve stimulation, which indicates that prejunctional CB1 receptors mediate the sympatho-inhibitory action. Thus cannabinoids can inhibit both the noradrenergic and purinergic components of sympathetic neurotransmission.

Central Nervous system

The noradrenergic neurons in the brain form a neurotransmitter system, that, when activated, exerts effects on large areas of the brain. The effects are manifested in alertness, arousal, and readiness for action.

Noradrenergic neurons (i.e. neurons whose primary neurotransmitter is norepinephrine) are comparatively few in number, and their cell bodies are confined to a few relatively small brain areas, but they send projections to many other brain areas and exert powerful effects on their targets. These noradrenergic cell groups were first mapped in 1964 by Annica Dahlström and Kjell Fuxe, who assigned them labels starting with the letter “A” (for “aminergic”). In their scheme, areas A1 through A7 contain the neurotransmitter norepinephrine (A8 through A14 contain dopamine). Noradrenergic cell group A1 is located in the caudal ventrolateral part of the medulla, and plays a role in the control of body fluid metabolism. Noradrenergic cell group A2 is located in a brainstem area called the solitary nucleus; these cells have been implicated in a variety of responses, including control of food intake and responses to stress. Cell groups A5 and A7 project mainly to the spinal cord.

The most important source of norepinephrine in the brain is the locus coeruleus, which contains noradrenergic cell group A6 and adjoins cell group A4. The locus coeruleus is quite small in absolute terms—in primates it is estimated to contain around 15,000 neurons, less than one-millionth of the neurons in the brain—but it sends projections to every major part of the brain and also to the spinal cord.

The level of activity in the locus coeruleus correlates broadly with vigilance and speed of reaction. LC activity is low during sleep and drops to virtually nothing during the REM (dreaming) state. It runs at a baseline level during wakefulness, but increases temporarily when a person is presented with any sort of stimulus that draws attention. Unpleasant stimuli such as pain, difficulty breathing, bladder distension, heat or cold generate larger increases. Extremely unpleasant states such as intense fear or intense pain are associated with very high levels of LC activity.

Norepinephrine released by the locus coeruleus affects brain function in a number of ways. It enhances processing of sensory inputs, enhances attention, enhances formation and retrieval of both long term and working memory, and enhances the ability of the brain to respond to inputs by changing the activity pattern in the prefrontal cortex and other areas. The control of arousal level is strong enough that drug-induced suppression of the LC has a powerful sedating effect.

There is great similarity between situations that activate the locus coeruleus in the brain and situations that activate the sympathetic nervous system in the periphery: the LC essentially mobilises the brain for action while the sympathetic system mobilises the body. It has been argued that this similarity arises because both are to a large degree controlled by the same brain structures, particularly a part of the brainstem called the nucleus gigantocellularis.

Skin

Norepinephrine is also produced by Merkel cells which are part of the somatosensory system. It activates the afferent sensory neuron.

Pharmacology

Refer to Norepinephrine (Medication).

A large number of important drugs exert their effects by interacting with norepinephrine systems in the brain or body. Their uses include treatment of cardiovascular problems, shock, and a variety of psychiatric conditions. These drugs are divided into: sympathomimetic drugs which mimic or enhance at least some of the effects of norepinephrine released by the sympathetic nervous system; sympatholytic drugs, in contrast, block at least some of the effects. Both of these are large groups with diverse uses, depending on exactly which effects are enhanced or blocked.

Norepinephrine itself is classified as a sympathomimetic drug: its effects when given by intravenous injection of increasing heart rate and force and constricting blood vessels make it very useful for treating medical emergencies that involve critically low blood pressure. Surviving Sepsis Campaign recommended norepinephrine as first line agent in treating septic shock which is unresponsive to fluid resuscitation, supplemented by vasopressin and epinephrine. Dopamine usage is restricted only to highly selected patients.

Antagonists

Beta Blockers

These are sympatholytic drugs that block the effects of beta adrenergic receptors while having little or no effect on alpha receptors. They are sometimes used to treat high blood pressure, atrial fibrillation and congestive heart failure, but recent reviews have concluded that other types of drugs are usually superior for those purposes. Beta blockers may be a viable choice for other cardiovascular conditions, though, including angina and Marfan syndrome. They are also widely used to treat glaucoma, most commonly in the form of eyedrops. Because of their effects in reducing anxiety symptoms and tremor, they have sometimes been used by entertainers, public speakers and athletes to reduce performance anxiety, although they are not medically approved for that purpose and are banned by the International Olympic Committee.

However, the usefulness of beta blockers is limited by a range of serious side effects, including slowing of heart rate, a drop in blood pressure, asthma, and reactive hypoglycaemia. The negative effects can be particularly severe in people with diabetes.

Alpha Blockers

These are sympatholytic drugs that block the effects of adrenergic alpha receptors while having little or no effect on beta receptors. Drugs belonging to this group can have very different effects, however, depending on whether they primarily block alpha-1 receptors, alpha-2 receptors, or both. Alpha-2 receptors, as described elsewhere in this article, are frequently located on norepinephrine-releasing neurons themselves and have inhibitory effects on them; consequently, blockage of alpha-2 receptors usually results in an increase in norepinephrine release. Alpha-1 receptors are usually located on target cells and have excitatory effects on them; consequently, blockage of alpha-1 receptors usually results in blocking some of the effects of norepinephrine. Drugs such as phentolamine that act on both types of receptors can produce a complex combination of both effects. In most cases when the term “alpha blocker” is used without qualification, it refers to a selective alpha-1 antagonist.

Selective alpha-1 blockers have a variety of uses. Since one of their effects is to inhibit the contraction of the smooth muscle in the prostate, they are often used to treat symptoms of benign prostatic hyperplasia. Alpha-blockers also likely help people pass their kidney stones. Their effects on the central nervous system make them useful for treating generalised anxiety disorder, panic disorder, and posttraumatic stress disorder (PTSD). They may, however, have significant side-effects, including a drop in blood pressure.

Some antidepressants function partly as selective alpha-2 blockers, but the best-known drug in that class is yohimbine, which is extracted from the bark of the African yohimbe tree. Yohimbine acts as a male potency enhancer, but its usefulness for that purpose is limited by serious side-effects including anxiety and insomnia. Overdoses can cause a dangerous increase in blood pressure. Yohimbine is banned in many countries, but in the United States, because it is extracted from a plant rather than chemically synthesized, it is sold over the counter as a nutritional supplement.

Alpha-2 Agonists

These are sympathomimetic drugs that activate alpha-2 receptors or enhance their effects. Because alpha-2 receptors are inhibitory and many are located presynaptically on norepinephrine-releasing cells, the net effect of these drugs is usually to reduce the amount of norepinephrine released. Drugs in this group that are capable of entering the brain often have strong sedating effects, due to their inhibitory effects on the locus coeruleus. Clonidine, for example, is used for the treatment of anxiety disorders and insomnia, and also as a sedative premedication for patients about to undergo surgery. Xylazine, another drug in this group, is also a powerful sedative and is often used in combination with ketamine as a general anaesthetic for veterinary surgery—in the United States it has not been approved for use in humans.

Stimulants and Antidepressants

These are drugs whose primary effects are thought to be mediated by different neurotransmitter systems (dopamine for stimulants, serotonin for antidepressants), but many also increase levels of norepinephrine in the brain. Amphetamine, for example, is a stimulant that increases release of norepinephrine as well as dopamine. Monoamine oxidase inhibitors are antidepressants that inhibit the metabolic degradation of norepinephrine as well as serotonin and dopamine. In some cases it is difficult to distinguish the norepinephrine-mediated effects from the effects related to other neurotransmitters.

Diseases and Disorders

A number of important medical problems involve dysfunction of the norepinephrine system in the brain or body.

Sympathetic Hyperactivation

Hyperactivation of the sympathetic nervous system is not a recognised condition in itself, but it is a component of a number of conditions, as well as a possible consequence of taking sympathomimetic drugs. It causes a distinctive set of symptoms including aches and pains, rapid heartbeat, elevated blood pressure, sweating, palpitations, anxiety, headache, paleness, and a drop in blood glucose. If sympathetic activity is elevated for an extended time, it can cause weight loss and other stress-related body changes.

The list of conditions that can cause sympathetic hyperactivation includes severe brain injury, spinal cord damage, heart failure, high blood pressure, kidney disease, and various types of stress.

Pheochromocytoma

A pheochromocytoma is a rarely occurring tumour of the adrenal medulla, caused either by genetic factors or certain types of cancer. The consequence is a massive increase in the amount of norepinephrine and epinephrine released into the bloodstream. The most obvious symptoms are those of sympathetic hyperactivation, including particularly a rise in blood pressure that can reach fatal levels. The most effective treatment is surgical removal of the tumour.

Stress

Stress, to a physiologist, means any situation that threatens the continued stability of the body and its functions. Stress affects a wide variety of body systems: the two most consistently activated are the hypothalamic-pituitary-adrenal axis and the norepinephrine system, including both the sympathetic nervous system and the locus coeruleus-centred system in the brain. Stressors of many types evoke increases in noradrenergic activity, which mobilises the brain and body to meet the threat. Chronic stress, if continued for a long time, can damage many parts of the body. A significant part of the damage is due to the effects of sustained norepinephrine release, because of norepinephrine’s general function of directing resources away from maintenance, regeneration, and reproduction, and toward systems that are required for active movement. The consequences can include slowing of growth (in children), sleeplessness, loss of libido, gastrointestinal problems, impaired disease resistance, slower rates of injury healing, depression, and increased vulnerability to addiction.

ADHD

Attention deficit hyperactivity disorder (ADHD) is a psychiatric condition involving problems with attention, hyperactivity, and impulsiveness. It is most commonly treated using stimulant drugs such as methylphenidate (Ritalin), whose primary effect is to increase dopamine levels in the brain, but drugs in this group also generally increase brain levels of norepinephrine, and it has been difficult to determine whether these actions are involved in their clinical value. There is also substantial evidence that many people with ADHD show biomarkers involving altered norepinephrine processing. Several drugs whose primary effects are on norepinephrine, including guanfacine, clonidine, and atomoxetine, have been tried as treatments for ADHD, and found to have effects comparable to those of stimulants.

Autonomic Failure

Several conditions, including Parkinson’s disease, diabetes and so-called pure autonomic failure, can cause a loss of norepinephrine-secreting neurons in the sympathetic nervous system. The symptoms are widespread, the most serious being a reduction in heart rate and an extreme drop in resting blood pressure, making it impossible for severely affected people to stand for more than a few seconds without fainting. Treatment can involve dietary changes or drugs.

REM Sleep Deprivation

Norepiprephine prevents REM sleep, and lack of REM sleep increases noradrenaline secretion as a result of the locus coeruleus not ceasing producing it. It causes neurodegeneration if its loss is sustained for several days.

Comparative Biology and Evolution

Norepinephrine has been reported to exist in a wide variety of animal species, including protozoa, placozoa and cnidaria (jellyfish and related species), but not in ctenophores (comb jellies), whose nervous systems differ greatly from those of other animals. It is generally present in deuterostomes (vertebrates, etc.), but in protostomes (arthropods, molluscs, flatworms, nematodes, annelids, etc.) it is replaced by octopamine, a closely related chemical with a closely related synthesis pathway. In insects, octopamine has alerting and activating functions that correspond (at least roughly) with the functions of norepinephrine in vertebrates. It has been argued that octopamine evolved to replace norepinephrine rather than vice versa; however, the nervous system of amphioxus (a primitive chordate) has been reported to contain octopamine but not norepinephrine, which presents difficulties for that hypothesis.

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What is a Dopamine Receptor?

Published on by Andrew Marshall7 Comments

Introduction

Dopamine receptors are a class of G protein-coupled receptors that are prominent in the vertebrate central nervous system (CNS).

Dopamine receptors activate different effectors through not only G-protein coupling, but also signalling through different protein (dopamine receptor-interacting proteins) interactions. The neurotransmitter dopamine is the primary endogenous ligand for dopamine receptors.

Dopamine receptors are implicated in many neurological processes, including motivational and incentive salience, cognition, memory, learning, and fine motor control, as well as modulation of neuroendocrine signalling. Abnormal dopamine receptor signalling and dopaminergic nerve function is implicated in several neuropsychiatric disorders. Thus, dopamine receptors are common neurologic drug targets; antipsychotics are often dopamine receptor antagonists while psychostimulants are typically indirect agonists of dopamine receptors.

Subtypes

The existence of multiple types of receptors for dopamine was first proposed in 1976. There are at least five subtypes of dopamine receptors, D1, D2, D3, D4, and D5. The D1 and D5 receptors are members of the D1-like family of dopamine receptors, whereas the D2, D3 and D4 receptors are members of the D2-like family. There is also some evidence that suggests the existence of possible D6 and D7 dopamine receptors, but such receptors have not been conclusively identified.

At a global level, D1 receptors have widespread expression throughout the brain. Furthermore, D1-2 receptor subtypes are found at 10–100 times the levels of the D3-5 subtypes.

D1-Like Family

The D1-like family receptors are coupled to the G protein G. D1 is also coupled to Golf.

Gsα subsequently activates adenylyl cyclase, increasing the intracellular concentration of the second messenger cyclic adenosine monophosphate (cAMP).

  • D1 is encoded by the Dopamine receptor D1 gene (DRD1).
  • D5 is encoded by the Dopamine receptor D5 gene (DRD5).

D2-Like Family

The D2-like family receptors are coupled to the G protein G, which directly inhibits the formation of cAMP by inhibiting the enzyme adenylyl cyclase.

  • D2 is encoded by the Dopamine receptor D2 gene (DRD2), of which there are two forms: D2Sh (short) and D2Lh (long):
    • The D2Sh form is pre-synaptically situated, having modulatory functions (viz., autoreceptors, which regulate neurotransmission via feedback mechanisms. It affects synthesis, storage, and release of dopamine into the synaptic cleft).
    • The D2Lh form may function as a classical post-synaptic receptor, i.e. transmit information (in either an excitatory or an inhibitory fashion) unless blocked by a receptor antagonist or a synthetic partial agonist.
  • D3 is encoded by the Dopamine receptor D3 gene (DRD3). Maximum expression of dopamine D3 receptors is noted in the islands of Calleja and nucleus accumbens.
  • D4 is encoded by the Dopamine receptor D4 gene (DRD4). The D4 receptor gene displays polymorphisms that differ in a variable number tandem repeat present within the coding sequence of exon 3. Some of these alleles are associated with greater incidence of certain disorders. For example, the D4.7 alleles have an established association with attention-deficit hyperactivity disorder.

Receptor Heteromers

Dopamine receptors have been shown to heteromerise with a number of other G protein-coupled receptors. Especially the D2 receptor is considered a major hub within the GPCR heteromer network. Protomers consist of:

  • Isoreceptors:
    • D1–D2
    • D1–D3
    • D2–D3
    • D2–D4
    • D2–D5
  • Non-isoreceptors:
    • D1–adenosine A1
    • D2–adenosine A2A
    • D2–ghrelin receptor
    • D2sh–TAAR1 (an autoreceptor heteromer)
    • D4–adrenoceptor α1B
    • D4–adrenoceptor β1

Signalling Mechanism

Dopamine receptor D1 and Dopamine receptor D5 are Gs coupled receptors that stimulate adenylyl cyclase to produce cAMP, which in turn increases intracellular calcium and mediates a number of other functions. The D2 class of receptors produce the opposite effect, as they are Gαi and/or Gαo coupled receptors, which blocks the activity of adenylyl cyclase. cAMP mediated protein kinase A activity also results in the phosphorylation of DARPP-32, an inhibitor of protein phosphatase 1. Sustained D1 receptor activity is kept in check by Cyclin-dependent kinase 5. Dopamine receptor activation of Ca2+/calmodulin-dependent protein kinase II can be cAMP dependent or independent.[18]

The cAMP mediated pathway results in amplification of PKA phosphorylation activity, which is normally kept in equilibrium by PP1. The DARPP-32 mediated PP1 inhibition amplifies PKA phosphorylation of AMPA, NMDA, and inward rectifying potassium channels, increasing AMPA and NMDA currents while decreasing potassium conductance.

cAMP Independent

D1 receptor agonism and D2 receptor blockade also increases mRNA translation by phosphorylating ribosomal protein s6, resulting in activation of mTOR. The behavioral implications are unknown. Dopamine receptors may also regulate ion channels and BDNF independent of cAMP, possibly through direct interactions. There is evidence that D1 receptor agonism regulates phospholipase C independent of cAMP, however implications and mechanisms remain poorly understood. D2 receptor signalling may mediate protein kinase B, arrestin beta 2, and GSK-3 activity, and inhibition of these proteins results in stunting of the hyperlocomotion in amphetamine treated rats. Dopamine receptors can also transactivate Receptor tyrosine kinases.

Beta Arrestin recruitment is mediated by G-protein kinases that phosphorylate and inactivate dopamine receptors after stimulation. While beta arrestin plays a role in receptor desensitisation, it may also be critical in mediating downstream effects of dopamine receptors. Beta arrestin has been shown to form complexes with MAP kinase, leading to activation of extracellular signal-regulated kinases. Furthermore, this pathway has been demonstrated to be involved in the locomotor response mediated by dopamine receptor D1. Dopamine receptor D2 stimulation results in the formation of an Akt/Beta-arrestin/PP2A protein complex that inhibits Akt through PP2A phosphorylation, therefore disinhibiting GSK-3.

Role in the Central Nervous System

Dopamine receptors control neural signalling that modulates many important behaviours, such as spatial working memory. Dopamine also plays an important role in the reward system, incentive salience, cognition, prolactin release, emesis and motor function.

Non-CNS Dopamine Receptors

Cardio-Pulmonary System

In humans, the pulmonary artery expresses D1, D2, D4, and D5 and receptor subtypes, which may account for vasodilatory effects of dopamine in the blood. Such receptor subtypes have also been discovered in the epicardium, myocardium, and endocardium of the heart. In rats, D1-like receptors are present on the smooth muscle of the blood vessels in most major organs.

D4 receptors have been identified in the atria of rat and human hearts. Dopamine increases myocardial contractility and cardiac output, without changing heart rate, by signalling through dopamine receptors.

Renal System

Dopamine receptors are present along the nephron in the kidney, with proximal tubule epithelial cells showing the highest density. In rats, D1-like receptors are present on the juxtaglomerular apparatus and on renal tubules, while D2-like receptors are present on the glomeruli, zona glomerulosa cells of the adrenal cortex, renal tubules, and postganglionic sympathetic nerve terminals. Dopamine signalling affects diuresis and natriuresis.

In Disease

Dysfunction of dopaminergic neurotransmission in the CNS has been implicated in a variety of neuropsychiatric disorders, including social phobia, Tourette’s syndrome, Parkinson’s disease, schizophrenia, neuroleptic malignant syndrome, attention-deficit hyperactivity disorder (ADHD), and drug and alcohol dependence.

Attention-Deficit Hyperactivity Disorder

Dopamine receptors have been recognised as important components in the mechanism of ADHD for many years. Drugs used to treat ADHD, including methylphenidate and amphetamine, have significant effects on neuronal dopamine signalling. Studies of gene association have implicated several genes within dopamine signalling pathways; in particular, the D4.7 variant of D4 has been consistently shown to be more frequent in ADHD patients. ADHD patients with the D4.7 allele also tend to have better cognitive performance and long-term outcomes compared to ADHD patients without the D4.7 allele, suggesting that the allele is associated with a more benign form of ADHD.

The D4.7 allele has suppressed gene expression compared to other variants.

Addictive Drugs

Dopamine is the primary neurotransmitter involved in the reward and reinforcement (mesolimbic) pathway in the brain. Although it was a long-held belief that dopamine was the cause of pleasurable sensations such as euphoria, many studies and experiments on the subject have demonstrated that this is not the case; rather, dopamine in the mesolimbic pathway is responsible for behaviour reinforcement (“wanting”) without producing any “liking” sensation on its own. Mesolimbic dopamine and its related receptors are a primary mechanism through which drug-seeking behaviour develops (Incentive Salience), and many recreational drugs, such as cocaine and substituted amphetamines, inhibit the dopamine transporter (DAT), the protein responsible for removing dopamine from the neural synapse. When DAT activity is blocked, the synapse floods with dopamine and increases dopaminergic signalling. When this occurs, particularly in the nucleus accumbens, increased D1 and decreased D2 receptor signalling mediates the “incentive salience” factor and can significantly increase positive associations with the drug in the brain.

Pathological Gambling

Pathological gambling is classified as a mental health disorder that has been linked to obsessive-compulsive spectrum disorder and behavioural addiction. Dopamine has been associated with reward and reinforcement in relation to behaviours and drug addiction. The role between dopamine and pathological gambling may be a link between cerebrospinal fluid measures of dopamine and dopamine metabolites in pathological gambling. Molecular genetic study shows that pathological gambling is associated with the TaqA1 allele of the Dopamine Receptor D2 (DRD2) dopamine receptor. Furthermore, TaqA1 allele is associated with other reward and reinforcement disorders, such as substance abuse and other psychiatric disorders. Reviews of these studies suggest that pathological gambling and dopamine are linked; however, the studies that succeed in controlling for race or ethnicity, and obtain DSM-IV diagnoses do not show a relationship between TaqA1 allelic frequencies and the diagnostic of pathological gambling.

Schizophrenia

Refer to Dopamine Hypothesis of Schizophrenia.

While there is evidence that the dopamine system is involved in schizophrenia, the theory that hyperactive dopaminergic signal transduction induces the disease is controversial. Psychostimulants, such as amphetamine and cocaine, indirectly increase dopamine signalling; large doses and prolonged use can induce symptoms that resemble schizophrenia. Additionally, many antipsychotic drugs target dopamine receptors, especially D2 receptors.

Genetic Hypertension

Dopamine receptor mutations can cause genetic hypertension in humans. This can occur in animal models and humans with defective dopamine receptor activity, particularly D1.

Parkinson’s Disease

Parkinson’s disease is associated with the loss of cells responsible for dopamine synthesis and other neurodegenerative events. Parkinson’s disease patients are treated with medications which help to replenish dopamine availability, allowing relatively normal brain function and neurotransmission. Research shows that Parkinson’s disease is linked to the class of dopamine agonists instead of specific agents. Reviews touch upon the need to control and regulate dopamine doses for Parkinson’s patients with a history of addiction, and those with variable tolerance or sensitivity to dopamine.

Dopamine Regulation

Refer to Yerkes–Dodson Law which is an empirical relationship between pressure and performance, originally developed by psychologists Robert M. Yerkes and John Dillingham Dodson in 1908. The law dictates that performance increases with physiological or mental arousal, but only up to a point. When levels of arousal become too high, performance decreases. The process is often illustrated graphically as a bell-shaped curve which increases and then decreases with higher levels of arousal. The original paper (a study of Japanese dancing mice) was only referenced ten times over the next half century, yet in four of the citing articles, these findings were described as a psychological “law”.

Dopamine receptors are typically stable, however sharp (and sometimes prolonged) increases or decreases in dopamine levels can downregulate (reduce the numbers of) or upregulate (increase the numbers of) dopamine receptors.

Haloperidol, and some other antipsychotics, have been shown to increase the binding capacity of the D2 receptor when used over long periods of time (i.e. increasing the number of such receptors). Haloperidol increased the number of binding sites by 98% above baseline in the worst cases, and yielded significant dyskinesia side effects.

Addictive stimuli have variable effects on dopamine receptors, depending on the particular stimulus. According to one study, cocaine, heroin, amphetamine, alcohol, and nicotine cause decreases in D2 receptor quantity. A similar association has been linked to food addiction (Park, 2007; Johnson & Kenny, 2010), with a low availability of dopamine receptors present in people with greater food intake. A 2008 news article summaried a US DOE Brookhaven National Laboratory study showing that increasing dopamine receptors with genetic therapy temporarily decreased cocaine consumption by up to 75%. The treatment was effective for 6 days. Cocaine upregulates D3 receptors in the nucleus accumbens, further reinforcing drug seeking behaviour.

Certain stimulants will enhance cognition in the general population (e.g. direct or indirect mesocortical DRD1 agonists as a class), but only when used at low (therapeutic) concentrations. Relatively high doses of dopaminergic stimulants will result in cognitive deficits.

This page is based on the copyrighted Wikipedia article < https://en.wikipedia.org/wiki/Dopamine_receptor >; it is used under the Creative Commons Attribution-ShareAlike 3.0 Unported License (CC-BY-SA). You may redistribute it, verbatim or modified, providing that you comply with the terms of the CC-BY-SA.

What is Dopamine Fasting?

Published on by Andrew Marshall1 Comment

Introduction

Dopamine fasting is a form of digital detox, involving temporarily abstaining from addictive technologies such as social media, listening to music on technological platforms, and Internet gaming, and can be extended to temporary deprivation of social interaction and eating. While the term’s origins are unknown; the concept was tackled seriously as a way to reduce impulsive behaviour in a guide as a CBT (Cognitive Behavioural Therapy) technique by Dr. Cameron Sepah.

The practice has been referred to as a “maladaptive fad” by one Harvard researcher. Other critics say that it is based on a misunderstanding of how the neurotransmitter dopamine, which operates within the brain to reward behaviour, actually works and can be altered by conscious behaviour. However, other scientists believe it is likely that both the practitioners and critics misunderstand the proposed technique, and rather the practice should be regarded as a self intervention for behavioural addiction. The idea behind it is to take a break from the repetitive patterns of excitement and stimulation that can be triggered by interaction with digital technology, and that the practice of avoiding pleasurable activities can work to undo bad habits, allow time for self-reflection, and bolster personal happiness.

Refer to Dopamine Receptor.

Definitions

The practice of dopamine fasting is not clearly defined in what it entails, on what technologies, with what frequency it should be done, or how it is supposed to work. Some proponents limit the process to avoiding online technology; others extend it to abstaining from all work, exercise, physical contact and unnecessary conversation.

According to Cameron Sepah, a proponent of the practice, the purpose is not to literally reduce dopamine in the body but rather to reduce impulsive behaviours that are rewarded by it. One account suggests that the practice is about avoiding cues, such as hearing the ring of a smartphone, that can trigger impulsive behaviours, such as remaining on the smartphone after the call to play a game. In one sense, dopamine fasting is a reaction to technology firms which have engineered their services to keep people hooked.

Dopamine fasting has been said to resemble the fasting tradition of many religions. An extreme form of dopamine fasting would be complete sensory deprivation, where all external stimuli are removed in order to promote a sense of calm and wellbeing.

Effects

Proponents of dopamine fasting argue that it is a way to exert greater self-control and self-discipline over one’s life, and New York Times technology journalist Nellie Bowles found that dopamine fasting made her subject’s everyday life “more exciting and fun”.

It has been described as a fad and a craze associated with Silicon Valley. An account in Vice, saying “If the idea of abstaining from anything fun in order to increase your mental clarity is appealing, congratulations: You and the notorious biohackers in Silicon Valley are on the same wave.”

Scientific Basis

Detractors say that the overall concept of dopamine fasting is unscientific since the chemical plays a vital role in everyday life; literally reducing it would not be good for a person, and removing a particular stimulus like social media would not reduce the levels of dopamine in the body, only the stimulation of it. Ciara McCabe, Associate Professor in Neuroscience at the University of Reading, considers the idea that the brain could be “reset” by avoiding dopamine triggers for a short time to be “nonsense”.

Cameron Sepah, who has promoted the practice of dopamine fasting, agrees that the name is misleading and says that its purpose is not to literally reduce dopamine in the body but rather to reduce the impulsive behaviours that are rewarded by it.

Besides the impulsive behaviour control – regulated by the prefrontal cortex, it has never been conclusively proven that technology use hardens the brain to dopamine’s effects. Technology use induces a dopamine response on par with any normal, enjoyable experience – roughly a 50% to 100% increase. By contrast, cocaine and methamphetamine – two highly addictive drugs – cause a dopamine spike of 350% and 1200% respectively. In addition, dopamine receptors themselves – the cells in the brain activated in different ways by dopamine’s release – respond differently to tech use than they do to substance abuse, with no evidence that they become less sensitive to dopamine with frequent tech use, in the way they do with substance abuse. In the final analysis, it is erroneous to assume that avoiding “dopamine spikes” may upregulate dopamine receptors, causing an “increase in motivation or pleasure”. Conversely, freeing oneself from bad habits may free up time for healthier habits, like physical activity, leading to actual increases in gray matter volume on multiple brain parts related to the reward system.

This page is based on the copyrighted Wikipedia article < https://en.wikipedia.org/wiki/Dopamine_fasting >; it is used under the Creative Commons Attribution-ShareAlike 3.0 Unported License (CC-BY-SA). You may redistribute it, verbatim or modified, providing that you comply with the terms of the CC-BY-SA.