Integrating Circadian and Reproductive Rhythms in Mood Regulation

Article information

Chronobiol Med. 2025;7(2):47-48

Publication date (electronic) : 2025 June 27

doi : https://doi.org/10.33069/cim.2025.0015

¹Graduate Institute of Mind, Brain and Consciousness (GIMBC), Taipei Medical University, New Taipei City, Taiwan

²Graduate Institute of Medical Sciences, College of Medicine, Taipei Medical University, Taipei, Taiwan

Corresponding author: Jihwan Myung, MS, PhD, Graduate Institute of Mind, Brain and Consciousness (GIMBC), Taipei Medical University, No. 301, Yuantong Rd., Zhonghe Dist., New Taipei City 235, Taiwan. Tel: 886-2-6620-2589, E-mail: jihwan@tmu.edu.tw

Received 2025 March 25; Revised 2025 April 29; Accepted 2025 May 4.

Maintaining a regular menstrual cycle is important for women’s psychological and physiological health beyond its reproductive role. However, the rhythmic structure of modern environments is often disrupted by nighttime exposure to artificial light, irregular shift work, and frequent jet lag, which disturb endogenous circadian rhythms. These disruptions disproportionately affect women and increase their susceptibility to mood disorders, including depression and bipolar disorder, with menstrual cycle disruption sometimes preceding mood symptoms [1]. Although lithium remains a primary mood stabilizer and is widely prescribed for bipolar disorder in women, its known effects on ovarian cycles raise concerns [2,3].

The ovarian cycle emerges from the interaction between biological oscillators operating on distinct timescales. A slow, infradian timer within the hypothalamic-pituitary-gonadal (HPG) axis integrates hormonal signals, notably estrogen (E2), and maintains a cycle of 28–29 days in humans and 4 days in rodents, while a system of circadian clocks in the hypothalamus and ovaries regulates the pulsatile release of gonadotropins on a much shorter timescale [4]. Both systems rely on feedback mechanisms, and despite cycle-to-cycle variability, the ovarian cycle functions as a long-term, highly precise clock [5]. These clocks of differing timescales interact in as-yet incompletely understood ways to maintain robust but adaptable physiological regulation over environmental and hormonal fluctuations.

The circadian circuit that mediates adaptation to jet lag also encodes seasonal photoperiod information [6]. Both menstrual and estrous cycles tend to lengthen under short photoperiods and shorten under long photoperiods. This implies that the hypothalamic circuitry regulating the ovarian cycle is intricately linked to the circadian clock. The suprachiasmatic nucleus (SCN), the central circadian pacemaker, contains arginine vasopressin (AVP)- and vasoactive intestinal polypeptide (VIP)-expressing neurons that serve distinct but complementary roles [7]. AVP neurons project to the anteroventral periventricular nucleus (AVPV), a key regulator of reproductive function and a site of kisspeptin-1 expression [8]. VIP neurons, by contrast, project to gonadotropin-releasing hormone (GnRH) neurons and upstream interneurons, and modulate circadian gating of reproductive output. Yet, despite extensive experimental data from anatomical and functional studies, the full logic of how these circadian signals are integrated into coherent reproductive rhythms remains unresolved.

This timing circuit is especially relevant in understanding how mood stabilizers adversely impact reproductive cycles in women. Lithium, widely used to treat mood disorders such as bipolar disorder, illustrates this circadian connection. It robustly lengthens circadian period and modulates molecular rhythms across species [9,10]. The dynamic interplay between circadian oscillators and the hormonal accumulator clock in the HPG axis may underlie the disruptive effects of lithium and other mood stabilizers that also affect circadian rhythms. An integrative understanding of rhythmic interactions within this circuit could lead to individualized treatments that balance mood stabilization with reproductive health.

The ovarian cycle serves as a tractable model to investigate how circadian clocks govern the rhythmic regulation of physiological and affective states. Addressing this intersection will likely require computational and theoretical frameworks that account for multitimescale circuit dynamics. Nevertheless, this integration can offer a promising path toward improving women’s mental and physical well-being through rhythm-informed diagnostics and therapies.

Notes

The author has no potential conflicts of interest to disclose.

Funding Statement

This work was supported by the National Science and Technology Council (NSTC), Taiwan (107-2311-B-038-001-MY2, 107-2410-H-038-004-MY2, 113-2314-B-038-121) and the Higher Education Sprout Project from the Ministry of Education (MOE), Taiwan.

Acknowledgments

None

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