The Mechanism of Pattern Transitions between Formation and Dispersion

Abstract

The patterns observed on the body surface of living organisms have traditionally been attributed solely to ecological strategies. However, this study investigates a fascinating phenomenon in Pelodiscus sinensis, where patterns formed on the plastron during embryonic and juvenile stages, which are not externally visible, ultimately disappear in adulthood. This exploration suggests the existence of mechanisms beyond ecological purposes in the formation of body surface patterns in living organisms. While numerous studies have examined pattern formation mechanisms, limited research has focused on the dispersion of preexisting patterns. This study aims to investigate the actual dispersion of patterns on the plastron of P.sinensis.Our research explores the role of osteoblasts expressing the enzyme cyp26b1, retinoic acid, and melanoblasts/melanophores on the ventral part of the plastron. We propose a hypothesis based on a reaction-diffusion system with a time-dependent growing spatial domain. This mathematical framework suggests the occurrence of the dispersion phenomenon. Specifically, we focus on the dilution term within the system under the growing-domain condition. In the context of black-pattern formation, we propose that variations in retinoic acid concentration, indirectly influenced by osteoblasts expressing the enzyme cyp26b1 during the embryonic/juvenile stage, contribute to the observed patterns. This hypothesis is grounded in the concept of prioritized osteogenesis and ossification during the embryonic/juvenile phase. This study expands our understanding of the species' survival strategy, highlighting the significance of bone biology and retinoic acid regulation. The findings have broader implications beyond P.sinensis, contributing to our knowledge of pattern formation and bone development in other organisms.