Recent groundbreaking research from Osaka Metropolitan University (OMU) unveils an extraordinary parallel in evolutionary biology: dragonflies possess the ability to detect red light in a manner strikingly similar to mammals, including humans. This discovery not only sheds light on the complexity of insect vision but also opens up exciting possibilities for medical technologies reliant on red and near-infrared light. The study reveals that dragonfly opsins, the light-sensitive proteins in their eyes, are finely tuned to perceive wavelengths beyond the familiar red spectrum visible to humans, highlighting an advanced sensory adaptation that supports mate recognition and other critical behaviors.
Color perception in most animals, humans included, is governed by a class of proteins known as opsins. These proteins absorb light at specific wavelengths, initiating signals that the brain interprets as color. Humans deploy three primary opsins sensitive to blue, green, and red light, enabling a wide range of color visions. Insects, however, traditionally have more limited color detection, making the discovery of dragonfly opsins attuned to deep red light particularly remarkable. The research team, led by Professors Mitsumasa Koyanagi and Akihisa Terakita, identified a novel opsin variant in dragonflies that responds to wavelengths around 720 nanometers (nm), which veers just beyond the visible red light humans perceive.
This depth of red light sensitivity is exceptional among insects, whose visual pigments mostly peak within a narrower light spectrum. The dragonfly’s ability to discern near-infrared wavelengths suggests highly specialized visual machinery that may provide evolutionary advantages in mate recognition and environmental interaction. The study hypothesizes that such sensitivity aids dragonflies in distinguishing between sexes through subtle differences in coloration and reflectance, a critical function for mating success during rapid aerial chases. Reflectance measurements—quantifying light reflected off surfaces—demonstrated marked disparities in red-near infrared reflectivity between male and female dragonflies, reinforcing the suggestion that these spectral cues facilitate swift and accurate sex identification.
What elevates this finding to a biological marvel is the convergence of molecular mechanisms underlying red light sensitivity between species distantly separated by evolutionary history. The dragonfly’s red opsin detects light through a mechanism that mirrors mammalian red opsins, an unexpected case of what scientists term “parallel evolution.” This process entails independently evolved traits that result in similar functional capabilities despite a significant gap in common ancestry. As graduate researcher Ryu Sato notes, the identical tuning mechanism in dragonflies and mammals underscores nature’s propensity for convergent solutions to analogous environmental challenges.
Delving deeper into the molecular underpinnings, the scientists found that a single amino acid position within the opsin protein plays a pivotal role in controlling its sensitivity to light wavelength. By modifying this critical site, they engineered a variant of the dragonfly opsin with even greater sensitivity extending further into the near-infrared range. This protein modification allowed cellular systems containing the altered opsin to be activated by near-infrared light, a wavelength previously out of reach for biological photoreceptors. Such bioengineering achievements signify a potential leap forward for medical applications relying on light activation.
One of the most promising applications emerging from this research lies in the realm of optogenetics, a flourishing field that utilizes genetically encoded light-sensitive proteins to control cellular and neuronal activities with incredible precision. Traditional optogenetic tools commonly respond to visible light, which limits their effectiveness when targeting cells deep within complex tissues, where light penetration is restricted. By harnessing dragonfly opsins with enhanced near-infrared sensitivity, researchers now have access to molecular tools potentially capable of penetrating deeper into biological tissues, thereby expanding the scope and efficacy of optogenetic modulation in neurological and medical research.
Professor Koyanagi emphasized this technological frontier, highlighting the successful shift of the dragonfly opsin’s peak sensitivity closer to longer wavelengths. The engineered opsin’s responsiveness to near-infrared light suggests it could serve as an innovative optogenetic actuator sensitive even within living organisms’ depths. This breakthrough could propel advances in neuroscience, cancer treatment, and regenerative medicine, where remote control of cellular functions deep inside the body is paramount.
The implications of this research stretch beyond biomedical engineering. Understanding how dragonflies have evolved such sophisticated spectral sensitivity offers fertile ground for evolutionary biology, ecology, and visual neuroscience. The findings raise intriguing questions about how environmental light conditions and behavioral needs shape sensory systems across the animal kingdom and inspire biomimetic designs in optical devices.
Moreover, this discovery illustrates how studying non-model organisms—often overlooked in genetic or sensory research—can yield transformative insights. Dragonflies, ancient aerial predators with a lineage tracing back millions of years, now take center stage as a source of inspiration for next-generation biotechnologies. The intricate tuning of their visual pigments underscores the complexity and adaptability of sensory proteins and encourages a broader appreciation of natural diversity’s contributions to human advancement.
Published in the journal Cellular and Molecular Life Sciences, this study reinforces the potential for interdisciplinary synergy between zoology and medical sciences. It bridges fundamental biological research with cutting-edge technological innovation, paving the way for future investigations aimed at enhancing light-based therapeutic techniques and illuminating the mysteries of visual perception.
In conclusion, the research conducted at Osaka Metropolitan University not only deciphers an extraordinary sensory capability in dragonflies but also unlocks new doors for leveraging this natural blueprint in human health and disease treatment. This convergence of biology and technology exemplifies the power of evolutionary convergence to inspire novel solutions, showcasing how the deep reds of dragonfly vision might soon illuminate human medicine in unexpected, profound ways.
Subject of Research: Animals
Article Title: Dragonfly red opsins share a common tuning mechanism with mammalian red opsins and further enhancement of near-infrared sensitivity
News Publication Date: 20-Jan-2026
References: http://dx.doi.org/10.1007/s00018-025-06017-9
Image Credits: Osaka Metropolitan University
Keywords: Dragonfly vision, red opsins, near-infrared light, parallel evolution, optogenetics, sensory proteins, molecular evolution, bioengineering, light sensitivity, cellular activation, visual pigments, medical technology
Tags: advanced insect color detectioncomparative vision mechanisms mammals and insectsdragonfly mate recognition and visiondragonfly red light detectiondragonfly sensory adaptationevolutionary biology of color perceptioninsect opsins and human visionmedical applications of red lightnovel opsin variants in insectsopsin protein function in visionred and near-infrared light sensingwavelength sensitivity in animal vision
