Monoamine oxidase explained

Symbol:MAO
Monoamine oxidase
Pfam:PF01593
Interpro:IPR001613
Opm Family:119
Opm Protein:2z5x
Membranome Family:418
monoamine oxidase A
Caption:Ribbon diagram of a monomer of human MAO-A, with FAD and clorgiline bound, oriented as if attached to the outer membrane of a mitochondrion. From .
Hgncid:6833
Symbol:MAOA
Entrezgene:4128
Omim:309850
Refseq:NM_000240
Uniprot:P21397
Chromosome:X
Arm:p
Band:11
Locussupplementarydata:.4-p11.3
monoamine oxidase B
Caption:Ribbon diagram of human MAO-B. From .
Hgncid:6834
Symbol:MAOB
Entrezgene:4129
Omim:309860
Refseq:NM_000898
Uniprot:P27338
Chromosome:X
Arm:p
Band:11
Locussupplementarydata:.4-p11.3

Monoamine oxidases (MAO) are a family of enzymes that catalyze the oxidation of monoamines, employing oxygen to clip off their amine group.[1] [2] They are found bound to the outer membrane of mitochondria in most cell types of the body. The first such enzyme was discovered in 1928 by Mary Bernheim in the liver and was named tyramine oxidase.[3] [4] The MAOs belong to the protein family of flavin-containing amine oxidoreductases.[5]

MAOs are important in the breakdown of monoamines ingested in food, and also serve to inactivate monoamine neurotransmitters. Because of the latter, they are involved in a number of psychiatric and neurological diseases, some of which can be treated with monoamine oxidase inhibitors (MAOIs) which block the action of MAOs.[6]

Subtypes and tissue distribution

In humans there are two types of MAO: MAO-A and MAO-B.[7]

MAO-A appears at roughly 80% of adulthood levels at birth, increasing very slightly after the first 4 years of life, while MAO-B is almost non-detectable in the infant brain. Regional distribution of the monoamine oxidases is characterized by extremely high levels of both MAOs in the hypothalamus and hippocampal uncus, as well as a large amount of MAO-B with very little MAO-A in the striatum and globus pallidus. The cortex has relatively high levels of only MAO-A, with the exception of areas of the cingulate cortex, which contains a balance of both. Autopsied brains demonstrated the predicted increased concentration of MAO-A in regions dense in serotonergic neurotransmission, however MAO-B only correlated with norepinephrine.[8]

Other studies, in which the activities of MAO (not protein amounts) were examined in rat brain, revealed the highest MAO-B activity in the median eminence of hypothalamus. Dorsal raphe nucleus and medial preoptic area have relatively high MAO-B activity, but much lower than MAO-B activity in the median eminence.[9] [10] Among cerebral endocrine glands, pineal gland has high MAO-B activity (its median value is lower than that for median eminence and higher than that for medial preoptic area). Pituitary has the lowest level of MAO-B activity when compared with brain areas studied.

Function

Monoamine oxidases catalyze the oxidative deamination of monoamines. In the first part of reaction, cofactor FAD oxidase substrate yielding corresponding imine which converts the cofactor into its reduced form FADH2. Imine is then non-enzymatically hydrolyzed to corresponding ketone (or aldehyde) and ammonia. Oxygen is used to restore reduced FADH2 cofactor back to the active FAD form. Monoamine oxidases contain the covalently bound cofactor FAD and are, thus, classified as flavoproteins. Monoamine oxidase A and B share roughly 70% of their structure and both have substrate binding sites that are predominantly hydrophobic. Two tyrosine residues (398, 435 within MAO-B, 407 and 444 within MAO-A) in the binding pocket that are commonly involved in inhibitor activity have been hypothesized to be relevant to orienting substrates, and mutations of these residues are relevant to mental health. Four main models have been proposed for the mechanism of electron transfer (single electron transfer, hydrogen atom transfer, nucleophilic model, and hydride transfer[11]) although there is insufficient evidence to support any of them.[12]

Substrate specificities

Monoamine oxidases are well known enzymes in pharmacology, since they are the target for the action of a number of monoamine oxidase inhibitor drugs. MAO-A is particularly important in the catabolism of monoamines ingested in food. Both MAOs are also vital to the inactivation of monoamine neurotransmitters, for which they display different specificities.

Specific reactions catalyzed by MAO include:

Clinical significance

Because of the vital role that MAOs play in the inactivation of neurotransmitters, MAO dysfunction (too much or too little MAO activity) is thought to contribute to a number of psychiatric and neurological disorders. Unusually high or low levels of MAOs in the body have been associated with schizophrenia,[15] [16] depression,[17] attention deficit disorder,[18] substance abuse,[19] migraines,[20] [21] and irregular sexual maturation. Monoamine oxidase inhibitors are one of the major classes of drug prescribed for the treatment of depression, although they are often last-line treatment due to risk of the drug's interaction with diet or other drugs. Excessive levels of catecholamines (epinephrine, norepinephrine, and dopamine) may lead to a hypertensive crisis, and excessive levels of serotonin may lead to serotonin syndrome.

In fact, MAO-A inhibitors act as antidepressant and anti-anxiety agents, whereas MAO-B inhibitors are used alone or in combination to treat Alzheimer's disease and Parkinson's disease.[22] Some research suggests that certain phenotypes of depression, such as those with anxiety, and "atypical" symptoms involving psychomotor retardation, weight gain and interpersonal sensitivity respond better to MAO inhibitors than other classes of anti-depressant. However the findings related to this have not been consistent.[23] MAOIs may be effective in treatment resistant depression, especially when it does not respond to tricyclic antidepressants.[24]

Parasite interactions

Sleeping sickness - caused by trypanosomes - gets its name from the sleep disruption it causes in mammals. That sleep disruption is caused, at least in part, by trypanosomes' tendency to disrupt MAO activity in the orexin system.

Animal models

There are significant differences in MAO activity in different species. Dopamine is primarily deaminated by MAO-A in rats, but by MAO-B in vervet monkeys and humans.[25]

Mice unable to produce either MAO-A or MAO-B display autistic-like traits.[26] These knockout mice display an increased response to stress.[27]

Arthropods

Insects

Insect brains express MAOs, and some insecticides work by inhibiting them. An MAOI effect is especially important for chlordimeform (although one result shows little or no effect in Periplaneta americana); and dieldrin may or may not be an MAOI in Locusta migratoria.

Acari

MAO activity has been detected in Rhipicephalus microplus and chlordimeform is an MAOI in R. m..

Genetics

The genes encoding MAO-A and MAO-B are located side-by-side on the short arm of the X chromosome, and have about 70% sequence similarity. Rare mutations in the gene are associated with Brunner syndrome.

A study based on the Dunedin cohort concluded that maltreated children with a low-activity polymorphism in the promoter region of the MAO-A gene were more likely to develop antisocial conduct disorders than maltreated children with the high-activity variant.[28] Out of the 442 total males in the study (maltreated or not), 37% had the low activity variant. Of the 13 maltreated males with low MAO-A activity, 11 had been assessed as exhibiting adolescent conduct disorder and 4 were convicted for violent offenses. The suggested mechanism for this effect is the decreased ability of those with low MAO-A activity to quickly degrade norepinephrine, the synaptic neurotransmitter involved in sympathetic arousal and rage. This is argued to provide direct support for the idea that genetic susceptibility to disease is not determined at birth, but varies with exposure to environmental influences. However, most individuals with conduct disorder or convictions did not have low activity of MAO-A; maltreatment was found to have caused stronger predisposition for antisocial behavior than differences in MAO-A activity.

The claim that an interaction between low MAO-A activity and maltreatment would cause anti-social behavior has been criticized since the predisposition towards anti-social behavior could equally well have been caused by other genes inherited from abusive parents.[29]

A possible link between predisposition to novelty seeking and a genotype of the MAO-A gene has been found.[30]

A particular variant (or genotype), dubbed "warrior gene" in the popular press, was over-represented in Māori. This supported earlier studies finding different proportions of variants in different ethnic groups. This is the case for many genetic variants, with 33% White/Non-Hispanic, 61% Asian/Pacific Islanders having the low-activity MAO-A promoter variant.[31]

Aging

Unlike many other enzymes, MAO-B activity is increased during aging in the brain of humans and other mammals.[32] Increased MAO-B activity was also found in the pineal gland of aging rats. This may contribute to lowered levels of monoamines in aged brain and pineal gland.[33]

See also

Notes and References

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  4. Slotkin TA . Mary Bernheim and the discovery of monoamine oxidase . Brain Research Bulletin . 50 . 5–6 . 373 . 1999 . 10643441 . 10.1016/S0361-9230(99)00110-0 . 35565156.
  5. Web site: CDD Conserved Protein Domain Family: Amino_oxidase .
  6. Yeung AW, Georgieva MG, Atanasov AG, Tzvetkov NT . 2019 . Monoamine Oxidases (MAOs) as Privileged Molecular Targets in Neuroscience: Research Literature Analysis . Frontiers in Molecular Neuroscience . 12 . 143 . 10.3389/fnmol.2019.00143 . 6549493 . 31191248 . free.
  7. Jean Chen Shih . Shih JC, Chen K . August 2004 . Regulation of MAO-A and MAO-B gene expression . Current Medicinal Chemistry . 11 . 15 . 1995–2005 . 10.2174/0929867043364757 . 15279563.
  8. Tong J, Meyer JH, Furukawa Y, Boileau I, Chang LJ, Wilson AA, Houle S, Kish SJ . June 2013 . Distribution of monoamine oxidase proteins in human brain: implications for brain imaging studies . Journal of Cerebral Blood Flow and Metabolism . 33 . 6 . 863–71 . 10.1038/jcbfm.2013.19 . 3677103 . 23403377.
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  11. Vianello R, Repič M, Mavri J . 2012-10-25. How are Biogenic Amines Metabolized by Monoamine Oxidases? . European Journal of Organic Chemistry . 2012 . 36 . 7057–7065 . 10.1002/ejoc.201201122.
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  14. Cho HU, Kim S, Sim J, Yang S, An H, Nam MH, Jang DP, Lee CJ . Redefining differential roles of MAO-A in dopamine degradation and MAO-B in tonic GABA synthesis . Exp Mol Med . 53 . 7 . 1148–1158 . July 2021 . 34244591 . 8333267 . 10.1038/s12276-021-00646-3 .
  15. Domino EF, Khanna SS . Decreased blood platelet MAO activity in unmedicated chronic schizophrenic patients . The American Journal of Psychiatry . 133 . 3 . 323–6 . March 1976 . 943955 . 10.1176/ajp.133.3.323 .
  16. Schildkraut JJ, Herzog JM, Orsulak PJ, Edelman SE, Shein HM, Frazier SH . Reduced platelet monoamine oxidase activity in a subgroup of schizophrenic patients . The American Journal of Psychiatry . 133 . 4 . 438–40 . April 1976 . 1267046 . 10.1176/ajp.133.4.438 .
  17. Meyer JH, Ginovart N, Boovariwala A, Sagrati S, Hussey D, Garcia A, Young T, Praschak-Rieder N, Wilson AA, Houle S . Elevated monoamine oxidase a levels in the brain: an explanation for the monoamine imbalance of major depression . Archives of General Psychiatry . 63 . 11 . 1209–16 . November 2006 . 17088501 . 10.1001/archpsyc.63.11.1209 .
  18. Domschke K, Sheehan K, Lowe N, Kirley A, Mullins C, O'sullivan R, Freitag C, Becker T, Conroy J, Fitzgerald M, Gill M, Hawi Z . Association analysis of the monoamine oxidase A and B genes with attention deficit hyperactivity disorder (ADHD) in an Irish sample: preferential transmission of the MAO-A 941G allele to affected children . American Journal of Medical Genetics. Part B, Neuropsychiatric Genetics . 134B . 1 . 110–4 . April 2005 . 15717295 . 10.1002/ajmg.b.30158 . 24453719 .
  19. Oreland L . Platelet monoamine oxidase, personality and alcoholism: the rise, fall and resurrection . Neurotoxicology . 25 . 1–2 . 79–89 . January 2004 . 14697883 . 10.1016/S0161-813X(03)00115-3 . 2004NeuTx..25...79O .
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  21. Filic V, Vladic A, Stefulj J, Cicin-Sain L, Balija M, Sucic Z, Jernej B . Monoamine oxidases A and B gene polymorphisms in migraine patients . Journal of the Neurological Sciences . 228 . 2 . 149–53 . February 2005 . 15694196 . 10.1016/j.jns.2004.11.045 . 572208 .
  22. Riederer P, Lachenmayer L, Laux G . Clinical applications of MAO-inhibitors . Current Medicinal Chemistry . 11 . 15 . 2033–43 . August 2004 . 15279566 . 10.2174/0929867043364775 . 2024-04-05 .
  23. Maj M, Stein DJ, Parker G, Zimmerman M, Fava GA, De Hert M, Demyttenaere K, McIntyre RS, Widiger T, Wittchen HU . The clinical characterization of the adult patient with depression aimed at personalization of management . World Psychiatry . 19 . 3 . 269–293 . October 2020 . 32931110 . 7491646 . 10.1002/wps.20771 .
  24. Fiedorowicz JG, Swartz KL . The role of monoamine oxidase inhibitors in current psychiatric practice . Journal of Psychiatric Practice . 10 . 4 . 239–48 . July 2004 . 15552546 . 2075358 . 10.1097/00131746-200407000-00005 .
  25. Garrick NA, Murphy DL . Species differences in the deamination of dopamine and other substrates for monoamine oxidase in brain . Psychopharmacology . 72 . 1 . 27–33 . 1980 . 6781004 . 10.1007/bf00433804 . 30722852 .
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    • Heidi Dawley . June 18, 2006 . The disorder of these times, neophilia . Media Life . https://web.archive.org/web/20070930153607/http://www.medialifemagazine.com/cgi-bin/artman/exec/view.cgi?archive=226&num=5439 . 2007-09-30.
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