Epigenetic plasticity in the pineal gland revealed by sex-specific DMR dynamics after chronic light stress exposure. A central Venn diagram illustrates the number of differentially methylated regions (DMRs) that were lost (orange), retained (overlapping), or gained (blue) between sexes after chronic light stress. Surrounding heatmaps display methylation levels (white to red, increasing intensity) for each DMR category across female (black) and male (gray) individuals under control (blue) or stress (yellow) conditions. Left heatmap (Lost): DMRs present in the control group but absent after stress. Female and male birds show clear differences under control, but these distinctions vanish under stress. Top right heatmap (Gained): New DMRs emerging after stress exposure. Although fewer, these regions highlight sex-specific changes induced by stress. Bottom right heatmap (Retained): DMRs conserved between conditions. These regions maintain consistent sex-specific methylation patterns regardless of treatment. This figure adapted from our published paper (in the reference), highlights how unpredictable light exposure alters the epigenetic landscape, erasing or reshaping sex-specific methylation patterns in the pineal gland of chickens. Credit: Adapter from Fabio Pertille et al. Sex-Specific Methylomic and Transcriptomic Responses of the Avian Pineal Gland to Unpredictable Illumination Patterns, Journal of Pineal Research (2025). DOI: 10.1111/jpi.70040
Light helps us wake up, keeps us alert, and guides our sleep. But what happens when light becomes erratic? As a researcher studying molecular biology and animal stress responses, I've been fascinated by how environmental changes affect living organisms in subtle but powerful ways. In our in the Journal of Pineal Research, we discovered that irregular light exposure disrupts the natural molecular differences between male and female birds鈥攅specially in the brain.
We already know that light regulates biological rhythms in most animals. In chickens, for example, artificial lighting is commonly used to boost growth and reproduction. But beyond farming practices, I wanted to know how unpredictable light affects the brain鈥攎ore specifically, the pineal gland, which plays a central role in regulating circadian rhythms through melatonin.
In collaboration with researchers at Uppsala University in Sweden and the University of S茫o Paulo in Brazil, we exposed chickens to an unpredictable light schedule during early life. Then we examined their brains to assess changes in gene activity, microRNAs, and DNA methylation鈥攃hemical markers that regulate how genes are expressed.
What we found surprised us.
The differences between males and females in the pineal gland almost disappeared under chronic light stress. This loss was most evident in the epigenome鈥攖he layer of regulation that turns genes on or off without altering DNA. Interestingly, while the epigenetic differences faded, the gene activity still showed clear sex-specific patterns. This suggests the body may try to compensate when epigenetic regulation is disturbed.
One striking discovery was how much this disruption affected females. In control conditions, we saw robust molecular differences between sexes. Under stress, those differences vanished almost entirely in females, particularly in genes located on the Z chromosome鈥攐ne of the sex chromosomes in birds.
As my colleague鈥攁nd also author of the paper鈥擠r. Carlos Guerrero-Bosagna said, "This suggests female birds are particularly vulnerable to environmental stress at the molecular level. These findings raise questions not just about animal welfare, but also about how artificial lighting may affect biological rhythms in other species, including humans."
While our study focused on birds, the implications are broader. Today, many people experience erratic light exposure due to shift work, artificial lighting, or digital screens. If unpredictable light can erase fundamental molecular differences in birds, what might it be doing to us?
This story is part of , where researchers can report findings from their published research articles. for information about Science X Dialog and how to participate.
More information: F谩bio P茅rtille et al, Sex鈥怱pecific Methylomic and Transcriptomic Responses of the Avian Pineal Gland to Unpredictable Illumination Patterns, Journal of Pineal Research (2025).
I am a researcher in epigenetics and molecular biology at Uppsala University in Sweden. My work focuses on how environmental factors, such as stress and light exposure, influence gene regulation in animals. I study mechanisms like DNA methylation and microRNA expression, with the aim of understanding their long-term effects on health and development. I hold a Ph.D. from the University of S茫o Paulo and collaborate with international teams on projects that connect animal biology with broader questions in translational science.
