Epigenetics and seasonal timing in animals: a concise review

Geographic Variation in Epigenetic Responses to Hypoxia in Deer Mice (Peromyscus maniculatus) Distributed Along an Elevational Gradient

Lowland and highland Peromyscus maniculatus populations display divergent, locally adapted physiological phenotypes shaped by altitudinal differences in oxygen availability. Many physiological responses to hypoxia seem to have evolved in lowland ancestors to offset episodic and localised bouts of low internal oxygen availability. However, upon chronic hypoxia exposure at high elevation, these responses can lead to physiological complications. Therefore, highland ancestry is often associated with evolved hypoxia responses, particularly traits promoting tolerance of constant hypoxia. Environmentally induced DNA methylation can dynamically alter gene expression patterns, providing a proximate basis for phenotypic plasticity. Given each population's differential reliance on plasticity for hypoxia tolerance, we hypothesised that lowland mice have a more robust epigenetic response to hypoxia exposure, driving trait plasticity, than highland mice. Using DNA methylation data of tissues from the heart's left ventricle, we show that upon hypoxia exposure, lowland mice chemically modulate the epigenetic landscape to a greater extent than highland mice, especially at key hypoxia-relevant genes such as Egln3. This gene is a regulator of the gene Epas1 that is frequently targeted for positive selection at high elevation. We find higher methylation among wild highland mice at gene Egln3 compared to wild lowland mice, suggesting a shared epigenetic ancestral response to episodic and chronic hypoxia. These findings highlight each population's distinct reliance on molecular plasticity driven by their unique evolutionary histories.

Intra- and interspecific temporal mating patterns in Anastrepha fraterculus and Anastrepha obliqua fruit flies

Daily rhythms, such as mating times, play a key role in shaping insect behavior and are pivotal in prezygotic reproductive isolation and speciation. To investigate whether mating behavior follows a daily rhythm under natural light-dark cycles and controlled temperature conditions, we examined the mating times of two related agricultural pest species, Anastrepha fraterculus and Anastrepha obliqua. Our observations revealed distinct patterns in their daily copulatory activities. A. fraterculus shows a unimodal pattern, peaking in the morning, while A. obliqua displays a bimodal pattern, with mating occurring in both the morning and late afternoon, all statistically validated. In A. obliqua, the morning peak is more pronounced before the winter solstice, reversing afterward. These results highlight the adaptability of these fruit flies' biological clocks, allowing them to adjust mating timing according to seasonal environmental changes. Our findings also reveal how each species gauges environmental light-dark durations, even if annual variation is less pronounced in tropical regions, with twilight serving as a daily marker. The observed plasticity, including phase shifts in both species and amplitude changes in A. obliqua, emphasizes their synchronization with environmental cycles, which may explain the absence of specific pre-mating behaviors and the initiation of mating in low-light conditions, as seen in A. fraterculus. This study underscores the importance of biological rhythm plasticity in understanding fruit fly mating behavior, with implications for population management and ecological dynamics, and reinforces the need for 24-h observations to capture these rhythms fully.

Seasonal Adaptation of Mammalian Development: Effect of Early-Life Photoperiod on Reproduction, Somatic Growth, and Neurobehavioral Systems

For the survival and efficient breeding of wild-living animals, it is crucial to predict seasonal changes and prepare appropriate physiological functions and neurobehavioral mechanisms. In mammals, photoperiod serves as a reliable cue for seasonal changes in the environment, primarily transmitted by melatonin. This review focuses on the seasonal adaptation of mammalian development, specifically the effect of early-life photoperiod on reproductive, somatic, and neurobehavioral development in small- and large-sized mammals. Prediction of seasons through early-life photoperiod is particularly important for small mammals, which have relatively short longevity, to adjust their maximum growth and breeding ability in appropriate seasons during the birth year or the following round. Brain plasticity, as well as cognitive and emotional behaviors, are also highly modulated by early-life photoperiods for successful mating and spatial memory for foraging. This review first summarizes the basic knowledge and recent progress in the programming and epigenetic regulatory mechanisms of reproductive and neurobehavioral development in small mammals, including C57BL/6J mice, which cannot produce detectable amounts of melatonin. The review then focuses on the influence of perinatal environmental conditions or birth season on adult phenotypes in large livestock and humans. Studies have advanced on the concept of the developmental origins of health and disease (DOHaD). Evidence from large mammals suggests that the prediction of seasons is crucial for high-fitness functions over several years. Finally, this review discusses the association of the season of birth with life course physiology and diseases in humans, and the possible mechanisms.

Erwin Bünning and Wolfgang Engelmann: establishing the involvement of the circadian clock in photoperiodism

In 1936, Erwin Bünning published his groundbreaking work that the endogenous clock is used to measure day length for initiating photoperiodic responses. His publication triggered years of controversial debate until it ultimately became the basic axiom of rhythm research and the theoretical pillar of chronobiology. Bünning's thesis is frequently quoted in the articles in this special issue on the subject of "A clock for all seasons". However, nowadays only few people know in detail about Bünning's experiments and almost nobody knows about the contribution of his former doctoral student, Wolfgang Engelmann, to his theory because most work on this topic is published in German. The aim of this review is to give an overview of the most important experiments at that time, including Wolfgang Engelmann's doctoral thesis, in which he demonstrated the importance of the circadian clock for photoperiodic flower induction in the Flaming Katy, Kalanchoë blossfeldiana, but not in the Red Morning Glory, Ipomoea coccinea.

A clock for all seasons

Circadian clocks play an essential role in adapting locomotor activity as well as physiological, and metabolic rhythms of organisms to the day-night cycles on Earth during the four seasons. In addition, they can serve as a time reference for measuring day length and adapt organisms in advance to annual changes in the environment, which can be particularly pronounced at higher latitudes. The physiological responses of organisms to day length are also known as photoperiodism. This special issue of the Journal of Comparative Physiology A aims to account for diurnal and photoperiodic adaptations by presenting a collection of ten review articles, five original research articles, and three perspective pieces. The contributions include historical accounts, circadian and photoperiodic clock models, epigenetic, molecular, and neuronal mechanisms of seasonal adaptations, latitudinal differences in photoperiodic responses and studies in the wild that address the challenges of global change.