2026-03-27 九州大学
精子形成の波の向きとその成り立ち:マウスで見られる精子形成の波の向きが精細管の伸びによって決まる可能性を示す模式図。
<関連情報>
- https://www.kyushu-u.ac.jp/ja/researches/view/1442
- https://www.kyushu-u.ac.jp/f/65228/26_0326_01.pdf
- https://www.sciencedirect.com/science/article/abs/pii/S0025556426000623
マウス精細管における分節波列と反転部位 Segmented wavetrains and sites of reversal in the mouse seminiferous tubules
Kei Sugihara, Ayuki Sekisaka, Toshiyuki Ogawa, Takashi Miura
Mathematical Biosciences Available online :26 March 2026
DOI:https://doi.org/10.1016/j.mbs.2026.109672
Highlights
- Segmented wavetrains reflect sites of reversal in seminiferous tubules.
- Segmented patterns frequently emerge but show no inherent directional bias.
- Tubule elongation may contribute to inward propagation near the rete testis.
- Segmented wavetrains are numerically stable and more frequent in longer domains.
- Interactions of local unidirectional wavetrains generate stable segmented structures.
Abstract
Mammalian spermatogenesis occurs in the seminiferous tubules, which exhibit unique spatiotemporal differentiation patterns known as cellular association patterns. In mice, these patterns can be regarded as one-dimensional wavetrains that consistently propagate inward from both ends, resulting in one or more “sites of reversal.” Segmented wavetrain pattern, in which the wave propagation direction spatially switches, was observed in our previous three-species reaction-diffusion model for interspecific species difference in spermatogenic waves [2]. However, the biological mechanisms of the formation of sites of reversal and of this directional bias, as well as the principle of pattern formation, remain unknown. Here, we refined our previous model to match the actual biological spatiotemporal scale and examined its dynamics through extensive numerical simulations. The modified model frequently generated segmented wavetrain patterns, corresponding to the sites of reversal, but without directional bias. We systematically examined possible biological mechanisms for the bias and found that tubule elongation, especially near the rete testis, most effectively accounts for the bias among the tested. Extensive simulations revealed that the segmented pattern is numerically stable, emerges more frequently in longer domains, and shows an exponential segment size distribution with a lower limit for the stably existing segment length. These explorations imply that locally emerged unidirectional wavetrains serve as building blocks to generate the stable segmented wavetrains through their interactions.
