Please cite this paper as:

Cachán-Vega, C., Boga, J.A., Potes, Y. and COTO MONTES, A. 2024. Onset in late adolescence of schizophrenia: could melatonin modulate this debut?. Melatonin Research. 7, 2 (Aug. 2024), 181-186. DOI:https://doi.org/https://doi.org/10.32794/mr112500174

Commentary 

Onset in late adolescence of schizophrenia: Could melatonin modulate this debut?

Cristina Cachán-Vega^1,2,3, Jose Antonio Boga ^1,2,4, Yaiza Potes^1,2,3, Ana Maria Coto-Montes A^1,2,3*

¹Instituto de Investigación Sanitaria del Principado de Asturias (ISPA), Av. del Hospital Universitario, s/n, 33011 Oviedo, Asturias, Spain

²Instituto de Neurociencias (INEUROPA), University of Oviedo, Julián Clavería, s/n, 33006 Oviedo, Asturias, Spain

³Department of Morphology and Cell Biology, Faculty of Medicine, University of Oviedo, Julián Clavería, s/n, 33006 Oviedo, Asturias, Spain

⁴Servicio de Microbiología, Hospital Universitario Central de Asturias (HUCA), Av. del Hospital Universitario, s/n, 33011 Oviedo, Asturias, Spain

*Correspondence: acoto@uniovi.es, Tel: 34-985102779 

Running title: Melatonin at the onset of schizophrenia

Receive: April 30, 2024; Accepted: August 30, 2024

ABSTRACT

     Schizophrenia, one of the most serious and widespread mental disorders in the world, makes its debut often in late adolescence and early adulthood, which allows us to focus our attention on those brain areas that still retain plasticity during this period. Parvalbumin interneurons, GABAergic and inhibitory, in both cortical and hippocampal areas, maintain their plasticity and are particularly vulnerable to oxidative stress due to their high energy requirements. Evidence has shown that their damage favors the triggering of schizophrenia by altering the neurobehavioral development of individuals. These neurons have melatonin receptors of MT1 and MT2, and the cytoprotective role of melatonin has been reported on these neurons. However, the role of this indolamine played in adolescence in protecting parvalbumin interneurons, reducing their oxidative stress and/or preventing their disappearance, which could prevent the onset of schizophrenia, is not yet known. The importance of this activity and its implications on patient therapy require the urgent studies.

___________________________________________________________________________________________________

Key words: Melatonin, schizophrenia, oxidative stress, neuronal plasticity, parvalbumin interneurons, late adolescence, mental disorders

1.      DEBUT OF SCHIZOPHRENIA: ROLE OF PARVALBUMIN INTERNEURONS

     Schizophrenia is one of the most serious neuropsychiatric disorders, both in terms of its pathophysiological development and its social course. Thus, in terms of clinical evolution, its onset is determined by a first psychotic episode, although some authors point to certain cognitive alterations that precede the onset of the disease and seem to worsen in the prodromal phase (1). Once the disease has occurred , it is characterized mainly by affective symptoms (1), including  depression or mania,  obvious impairments in attention, memory, planning (2, 3) and social relationships. Neuroimaging and neuropsychological studies show changes mainly in the temporolimbic and frontal lobe regions (4). But this disorder also causes drastic changes in the lives of the patients. Statistics show that most of them are condemned to social isolation, stigmatization, unemployment rates of between 70% and 90% in Europe, and significantly reduced chances of finding a partner (5). All this, combined with poorer health habits and co-morbidities, leads to a reduction in life expectancy of 13-15 years (6) and a suicide rate of around 5% of those diagnosed (7). In view of these devastating characteristics, it is imperative to develop new therapeutic strategies to improve the quality of life of these patients, which will necessarily require an increase in research efforts to understand the etiology and pathophysiology of the disease, which is currently very limited. We propose to focus the research on the early stages of the onset of this pathology, corresponding to late adolescence or early adulthood, since this is a particularly critical period for the onset of this disorder, while at the same time it is particularly complex due to the large number of hormonal changes that it involves, which, however, are not fully understood (8).

    Far from being the static system that it has been considered for decades, the central nervous system has certain regions that have a remarkable capacity for remodeling and this capacity  is preserved  not only during the early stage of life  but it is also carried out into adulthood (9), in particular the prefrontal cortex and the hippocampus (10). Two main populations of neurons arise in both regions: excitatory or glutamatergic neurons, which therefore use glutamate to communicate, and inhibitory or GABAergic interneurons, whose dependence on the expression of different calcium chelating proteins allows their classification (11). A malfunction or alteration in any of these regions that affects their integrity leads to different types of disorders (12, 13), among which schizophrenia stands out as a neuropsychiatric disorder that coincides with damage in one of the two mentioned areas (14, 15).

     Although the  alterations in both excitatory and inhibitory pathways  triggering the onset of schizophrenia have been suggested (8), there is greater agreement in emphasizing the importance of alterations in interneurons triggering this disorder (16, 17). Therefore, calcium-binding protein parvalbumin (PV) interneurons from both cortical (18) and hippocampal (19) areas have received particular attention in relation to this disorder. In fact, it has recently been shown that a significant reduction PV interneuron, as well as those whose neurotransmitter is somatostatin, during embryonic development causes neurophysiological and behavioral changes consistent with human schizophrenia in adult rats (20).

   Due to their high activity, PV interneurons require a high energy input, corresponding to the large number of mitochondria of these cells (21), making them particularly susceptible to oxidative stress (22). The ability of oxidative stress to cause significant cellular damage, particularly in the central nervous system, has been well established. However, if we consider  this new information of the long lasting  plasticity of these neurons until to the adulthood, the possible role of oxidative stress as an inducer of neuronal functional changes (23), as well as an imbalance in the excitatory/inhibitory status  (8), takes on a new meaning. Recently, the increased evidence has shown that the free radicals, which alter the maturation of PV interneurons, modulates the development of mental illness (24). If considering  the modulatory  role of the circadian rhythm on the maturation of PV interneurons (25), especially during critical developmental periods such as adolescence, the potential beneficial role of melatonin, at least, in the onset of this disorder, seems undeniable, although to our knowledge no article has yet mentioned it.

2.      MELATONIN AS A PROTECTIVE MOLECULE

     Melatonin has been shown to play a protective and beneficial role in a wide range of pathologies and disorders (26–29), due to its dual capacity as both a circadian rhythm regulator, marking the sleep-wake cycle (30, 31), and as a multifunctional antioxidant and free radical scavenger with anti-inflammatory capacity (32, 33). However, data on the benefits of melatonin in schizophrenia are still scattered and inconclusive (34), although not without importance and significance in this disorder. During embryonic development, the role of melatonin, mainly through its MT1 and MT2 receptors present in the fetal brain and leptomeninges (35), appears to be essential for neurodevelopment (36) and neuroprotection (37), as an anti-inflammatory agent with beneficial effects on the normal  development of neurobehavioral functions (38), often affected in schizophrenia (39). Indeed, in human olfactory neuronal precursors (ONPs), the markedly reduced differentiation capacity observed in schizophrenia patients has been demonstrated, particularly with regard to melatonergic receptors (40).

    In late adolescence and the transition to adulthood, the drastic decrease in melatonin production during this period is well known (41). Both cortical and hippocampal PV interneurons, which have not fully matured in late adolescence, are particularly sensitive to oxidative stress due to their high demanding on mitochondrial energy (21). This oxidative stress can be particularly dangerous at this stage of life, as it can induce an excitatory-inhibitory imbalance in these areas (8) and increase the risk of psychotic disorders (24, 42). In fact, a reduction of these interneurons has been observed in both the prefrontal cortex and the hippocampus in patients with schizophrenia (20, 43), which indirectly justifies their importance in the development of the disorder. At the same time, MT1 and MT2 receptors have been identified in these neurons, and their activation appears to increase the expression of the calcium-binding protein parvalbumin, thereby reducing neuronal inflammation (44). Suppression of MT1 and MT2 leads to increased glutamate toxicity in PV interneurons , which can be partially reversed by melatonin (44). Thus, the possible protective role of melatonin in this strategic phase of the transition to adulthood on the possible damage in these PVinterneurons seems evident. Although the protective role of melatonin on mitochondria is well known (45, 46), and it has even been found that patients with schizophrenia show a reduction in the size of their pineal gland (47), and the ability of melatonin to restore the reduced differentiation capacity of ONPs in schizophrenia patients has been demonstrated (40), few  studies  have  addressed the potential role of melatonin in protecting these neurons during the crucial period of life which is  closely associated to the onset of the first psychotic episode. The potential association of occurrence of Schizophora and the natural melatonin drop-out was illustrated in Figure 1.

Fig. 1. The potential effects of the natural melatonin drop-out at the late adolescence and the transition to adulthood on the occurrence of Schizophora.

      Melatonin levels fluctuate throughout a person's life, with an abrupt increase in melatonin production from childhood to adolescence (10-14 years), when melatonin production is maximal, and then with a rapid decline, reaching minimum production levels after the age of 55. The onset of the decline in melatonin production (adolescence - early adulthood) coincides with the maturation of parvalbumin interneurons, melatonin-sensitive neurons (with MT1 and MT2 receptors) whose involvement appears to be closely linked to the pathogenesis of schizophrenia. Graph of melatonin levels modified from information provided by the International Melatonin Institute (IiMEL).

     The extent, severity and disability caused by this pathology make it necessary to develop therapies. But it also makes it crucial to discover those processes that could reduce or prevent the onset of psychosis. And there are enough indirect data to support the possibility that melatonin could preserve and thus protect the PV interneurons and prevent the onset of schizophrenia.

ACKNOWLEDGMENTS

     CCV thanks her Severo Ochoa pre-doctoral fellowship to the Government of the Principado de Asturias, grant number PA-23-BP22-073. AC-M thanks to Instituto de Salud Carlos III, grant number FISS-PII21/01596 and the Fundación Mutua Madrileña, grant number AP-184182023.

AUTHORSHIPS

     ACM designed the idea for the article. CCV, JAB, YP and ACM performed the literature search and wrote the first draft of the manuscript.  ACM reviewed and revised the manuscript. ACM reviewed and approved the final version of the manuscript.

CONFLICT OF INTEREST

     The authors declare no conflict of interests.

REFERENCES

1. Kulak A, et al. (2013) Redox dysregulation in the pathophysiology of schizophrenia and bipolar disorder: insights from animal models. Antioxid. Redox. Signal 18: 1428–1443.

2. Turetsky BI, et al. (2007) Facial emotion recognition in schizophrenia: when and why does it go awry? Schizophr. Res. 94: 253–263.

3. Saykin AJ, et al. (1994) Neuropsychological deficits in neuroleptic naive patients with first-episode schizophrenia. Arch. Gen. Psychiatry 51: 124–131.

4. Turetsky B, et al. (1995) Frontal and temporal lobe brain volumes in schizophrenia. Relationship to symptoms and clinical subtype. Arch. Gen. Psychiatry 52: 1061–1070.

5. Marwaha S, et al. (2007) Rates and correlates of employment in people with schizophrenia in the UK, France and Germany. Br. J. Psychiatry 191: 30–37.

6. Hjorthøj C, Stürup AE, McGrath JJ, Nordentoft M (2017) Years of potential life lost and life expectancy in schizophrenia: a systematic review and meta-analysis. Lancet Psychiatry 4: 295–301.

7. Hor K, Taylor M (2010) Suicide and schizophrenia: a systematic review of rates and risk factors. J Psychopharmacol 24: 81–90.

8. Sullivan EM, O’Donnell P (2012) Inhibitory interneurons, oxidative stress, and schizophrenia. Schizophr Bull 38: 373–376.

9. Xerri C (2008) Imprinting of idiosyncratic experience in cortical sensory maps: neural substrates of representational remodeling and correlative perceptual changes. Behav. Brain Res. 192: 26–41.

10. Curto Y, et al. (2024) Erythropoietin restrains the inhibitory potential of interneurons in the mouse hippocampus. Mol. Psychiatry. https://doi.org/10.1038/s41380-024-02528-2.

11. Petilla Interneuron Nomenclature Group, et al. (2008) Petilla terminology: nomenclature of features of GABAergic interneurons of the cerebral cortex. Nat. Rev. Neurosci. 9: 557–568.

12. Kolb B, Mychasiuk R, Muhammad A, Gibb R (2013) Brain plasticity in the developing brain. Prog. Brain Res. 207: 35–64.

13. Kolb B, Gibb R (2015) Plasticity in the prefrontal cortex of adult rats. Front. Cell Neurosci. 9: 15.

14. Bicks LK, Koike H, Akbarian S, Morishita H (2015) Prefrontal cortex and social cognition in mouse and man. Front. Psychol. 6: 1805.

15. Anand KS, Dhikav V (2012) Hippocampus in health and disease: An overview. Ann. Indian Acad. Neurol. 15: 239–246.

16. Hunziker U, Largo R, Zachmann M, Prader A (1986) Compensatory maturational deceleration of growth or “catch-down growth” in patients with congenital adrenal hyperplasia after delayed initiation of therapy. Eur. J. Pediatr. 144: 550–553.

17. Steullet P, et al. (2017) Oxidative stress-driven parvalbumin interneuron impairment as a common mechanism in models of schizophrenia. Mol. Psychiatry 22: 936–943.

18. Khadimallah I, et al. (2022) Mitochondrial, exosomal miR137-COX6A2 and gamma synchrony as biomarkers of parvalbumin interneurons, psychopathology, and neurocognition in schizophrenia. Mol. Psychiatry 27: 1192–1204.

19. Perez SM, Boley A, Lodge DJ (2019) Region specific knockdown of Parvalbumin or Somatostatin produces neuronal and behavioral deficits consistent with those observed in schizophrenia. Transl. Psychiatry 9: 264.

20. Elam HB, Perez SM, Donegan JJ, Eassa NE, Lodge DJ (2024) Knockdown of Lhx6 during embryonic development results in neurophysiological alterations and behavioral deficits analogous to schizophrenia in adult rats. Schizophr. Res. 267: 113–121.

21. Kann O (2016) The interneuron energy hypothesis: Implications for brain disease. Neurobiol. Dis. 90: 75–85.

22. Kann O, Huchzermeyer C, Kovács R, Wirtz S, Schuelke M (2011) Gamma oscillations in the hippocampus require high complex I gene expression and strong functional performance of mitochondria.Brain 134: 345–358.

23. Santos-Silva T, et al. (2024) Adolescent stress-induced ventral hippocampus redox dysregulation underlies behavioral deficits and excitatory/inhibitory imbalance related to schizophrenia. Schizophr. Bull. sbae033. https://doi.org/10.1093/schbul/sbae033.

24. Santos-Silva T, et al. (2024) Perineuronal nets as regulators of parvalbumin interneuron function: Factors implicated in their formation and degradation. Basic. Clin. Pharmacol. Toxicol. 134: 614–628.

25. Gibel-Russo R, Benacom D, Di Nardo AA (2022) Non-cell-autonomous factors implicated in parvalbumin interneuron maturation and critical periods. Front. Neural. Circuits. 16: 875873.

26. Bagherifard A, et al. (2023) Melatonin and bone-related diseases: an updated mechanistic overview of current evidence and future prospects. Osteoporos. Int. 34: 1677–1701.

27. Targhazeh N, et al. (2022) Oncostatic activities of melatonin: Roles in cell cycle, apoptosis, and autophagy. Biochimie 202: 34–48.

28. Luo C, et al. (2019) The multiple protective roles and molecular mechanisms of melatonin and its precursor N-acetylserotonin in targeting brain injury and liver damage and in maintaining bone health. Free Radic. Biol. Med. 130: 215–233.

29. Pérez-Martínez Z, Boga JA, Potes Y, Melón S, Coto-Montes A (2024) Effect of melatonin on herpesvirus type 1 replication. Int J Mol Sci 25: 4037.

30. Hosseinzadeh A, et al. (2024) Therapeutic potential of melatonin in targeting molecular pathways of organ fibrosis. Pharmacol. Rep. 76: 25–50.

31. Li T, et al. (2019) Exogenous melatonin as a treatment for secondary sleep disorders: A systematic review and meta-analysis. Front. Neuroendocrinol. 52: 22–28.

32. Hosseinzadeh A. et al. (2024) Melatonin and oral diseases: possible therapeutic roles based on cellular mechanisms. Pharmacol Rep. 76 (3):487-503.

33. Mehrzadi S, et al. (2023) Protective and therapeutic potential of melatonin against intestinal diseases: updated review of current data based on molecular mechanisms. Expert. Rev. Gastroenterol. Hepatol. 17: 1011–1029.

34. Potes Y, et al. (2023) Benefits of the neurogenic potential of melatonin for treating neurological and neuropsychiatric disorders. Int. J. Mol. Sci. 24: 4803.

35. Thomas L, Purvis CC, Drew JE, Abramovich DR, Williams LM (2002) Melatonin receptors in human fetal brain: 2-[(125)I]iodomelatonin binding and MT1 gene expression. J. Pineal Res. 33: 218–224.

36. Jin Y, Choi J, Won J, Hong Y (2018) The Relationship between autism spectrum disorder and melatonin during fetal development. Molecules 23: 198.

37. Zhang Z, van Praag H (2015) Maternal immune activation differentially impacts mature and adult-born hippocampal neurons in male mice. Brain Behav. Immun. 45: 60–70.

38. Chitimus DM, et al. (2020) Melatonin’s impact on antioxidative and anti-inflammatory reprogramming in homeostasis and disease. Biomolecules 10: 1211.

39. Cowman M, et al. (2024) Measures of social and occupational function in early psychosis: A systematic review and meta-analysis. Schizophr. Bull. 50: 266–285.

40. Galván-Arrieta T, et al. (2017) The role of melatonin in the neurodevelopmental etiology of schizophrenia: A study in human olfactory neuronal precursors. J. Pineal Res. 63: e12421.

41. Waldhauser F, et al. (1984) Fall in nocturnal serum melatonin during prepuberty and pubescence. Lancet 1: 362–365.

42. Amminger GP, et al.  (2010) Long-chain omega-3 fatty acids for indicated prevention of psychotic disorders: a randomized, placebo-controlled trial. Arch. Gen. Psychiatry 67: 146–154.

43. Hashimoto T, et al. (2003) Gene expression deficits in a subclass of GABA neurons in the prefrontal cortex of subjects with schizophrenia. J. Neurosci. 23: 6315–6326.

44. Das A, et al. (2013) Overexpression of melatonin membrane receptors increases calcium-binding proteins and protects VSC4.1 motoneurons from glutamate toxicity through multiple mechanisms. J. Pineal Res. 54: 58–68.

45. Reiter RJ, Sharma R, Rosales-Corral S, de Campos Zuccari DAP, de Almeida Chuffa LG (2022) Melatonin: A mitochondrial resident with a diverse skill set. Life Sci. 301: 120612.

46. Ma Z, et al. (2017) Melatonin and mitochondrial function during ischemia/reperfusion injury. Cell. Mol. Life Sci. 74: 3989–3998.

47. Bastos MAV, et al. (2019) Pineal gland and schizophrenia: A systematic review and meta-analysis. Psychoneuroendocrinology 104: 100–114.

This work is licensed under a Creative Commons Attribution 4.0 International License