In a groundbreaking revelation that could reshape our understanding of skin biology, researchers at Washington State University have uncovered critical insights into the development of microscopic skin features known as rete ridges. This discovery defies longstanding assumptions that these complex biological structures are formed exclusively during fetal development. Instead, the study reveals that rete ridges emerge shortly after birth, driven by a specific molecular signaling pathway. This breakthrough holds vast potential for advancing therapies designed to combat skin aging, enhance wound healing, and improve scar repair.
Rete ridges are intricate, ridge-and-valley formations situated beneath the surface of the skin, playing an essential role in maintaining skin integrity. These structures function as biological “Velcro,” robustly anchoring the epidermis—the outermost skin layer—to the underlying dermis. This anchoring not only supports mechanical stability but also preserves skin elasticity and resilience. Unfortunately, as humans age, these rete ridges progressively flatten and degrade, contributing to thinner, more fragile skin prone to sagging and injury.
For decades, research into rete ridges has been hindered by the use of conventional animal models such as mice and non-human primates that lack these skin features due to their dense fur. Recognizing this limitation, the Washington State University team took an innovative comparative approach by examining a variety of mammals with thicker skin—namely pigs, grizzly bears, and dolphins. Intriguingly, these animals, which share a similar skin architecture with humans, possess well-defined rete ridges, unlike the fur-covered animals traditionally used in biomedical research.
The inclusion of grizzly bear skin in the analysis provided valuable evolutionary context. The study suggests that an animal’s body size correlates with specific skin structures; larger-bodied species like bears exhibit pronounced rete ridges. However, given the complexity and impracticality of studying the grizzly’s skin development in real-time, the researchers turned to pigs, whose developmental timeline is more manageable and physiologically comparable to humans.
Through meticulous examination of pig skin across various developmental stages, the researchers documented the formation of rete ridges occurring postnatally, contradicting the entrenched belief that these structures are established exclusively during gestation. This revelation shifts paradigms about skin development and significantly widens the window for potential therapeutic intervention aimed at preserving or restoring skin microarchitecture during adulthood and aging.
At the heart of rete ridge formation lies the activation of the bone morphogenetic protein (BMP) signaling pathway—an intricate molecular cascade essential for cellular communication and tissue organization. By employing cutting-edge genetic mapping techniques, the research team identified BMP as the pivotal driver orchestrating the emergence of rete ridges. This signaling pathway acts as a detailed set of molecular instructions directing skin cells to self-organize into the complex, undulating structures characteristic of healthy skin.
Reactivation or modulation of BMP signaling in aging skin presents a tantalizing therapeutic avenue. As rete ridges diminish with age, re-engaging this pathway could stimulate renewal and restoration of skin architecture, thereby improving skin elasticity, reducing susceptibility to damage, and enhancing healing responses. Such interventions could have profound implications not only for anti-aging cosmetic treatments but also for managing chronic wounds and pathological scarring.
The translational implications extend beyond human medicine. With increased understanding of rete ridge development mechanisms, there exists the potential to engineer livestock with skin traits optimized for resilience and adaptability to diverse environmental conditions. This could revolutionize animal husbandry by enhancing livestock health in varying climates, improving welfare, and potentially augmenting agricultural productivity.
The multidisciplinary collaboration underlying this study encompassed contributions from WSU’s Bear Research, Education and Conservation Center, local farming communities, the University of Washington Birth Defects Research Laboratory, and dermatology clinics in Spokane. Funded by significant grants from the National Institutes of Health and the USDA Agricultural Research Service under the Resilient Livestock Initiative, this research exemplifies a successful synergy between veterinary science, molecular biology, and clinical dermatology.
These findings have not only been published in the prestigious journal Nature but have also led to the filing of a provisional patent by lead researchers, underscoring the innovation’s potential commercial and therapeutic value. Given the FDA approval history for BMP proteins in orthodontic applications, leveraging BMP signaling pathways in dermatology might be a strategically viable next frontier with expedited clinical translation.
Looking ahead, this study opens up exciting new frontiers in skin biology research. Scientists can now explore the biological window post-birth during which skin structure can be influenced, offering hope for interventions well beyond prenatal stages. Furthermore, the identification of rete ridge formation’s molecular underpinnings will catalyze the development of targeted treatments aimed at skin regeneration and improved management of dermatological conditions such as psoriasis and other chronic inflammatory diseases.
In conclusion, this research heralds a new era in understanding the biology of skin microstructures that are central to maintaining youthful resilience and effective barrier function. The postnatal emergence of rete ridges, orchestrated by BMP signaling, overturns decades of assumptions and charts a promising course toward innovative therapies that could transform human health, cosmetic science, and veterinary medicine alike.
Subject of Research: Skin microstructures (rete ridges), molecular mechanisms of skin development, anti-aging therapies, wound healing, and scar repair.
Article Title: Postnatal Development and Molecular Regulation of Rete Ridges in Mammalian Skin
News Publication Date: 4-Feb-2026
Web References:
https://www.nature.com/articles/s41586-025-10055-5
http://dx.doi.org/10.1038/s41586-025-10055-5
References:
Driskell, R. et al. (2026). Postnatal formation and BMP signaling-driven development of rete ridges in mammalian skin. Nature. https://doi.org/10.1038/s41586-025-10055-5
Keywords: rete ridges, skin aging, BMP signaling, epidermis, dermis, skin microstructure, wound healing, scar repair, molecular biology, veterinary science, pig skin development, regenerative medicine
Tags: animal models in biomedical researchbiological functions of rete ridgesbreakthrough discoveries in skin scienceimpact of aging on skin structureinnovative research methods in dermatologymolecular signaling pathways in skin developmentpigs as animal models for skin researchrete ridges and skin biologyskin aging therapies and treatmentsskin integrity and elasticityunderstanding skin features post-birthwound healing and scar repair advancements
