Hofstenia miamia. Image credit: Chandra et al. (CC BY-4.0)
Biology is built on a foundation of natural history: a basic understanding of the anatomy, physiology, and behavior of animals in both laboratory and field settings. Centuries of research have provided extensive knowledge about some organisms, yet many animals –such as acoels – remain largely mysterious.
Acoels, a phylum of mostly marine worms, are likely the outgroup to all other Bilateria. Studying acoels and their relatives is therefore vital for understanding the evolution of animal body plans, organs, and other essential traits. Many acoels also have the remarkable ability to regenerate any missing tissue from almost any starting point, and recent advances have established them as a promising model for studying regeneration.
However, fundamental aspects of their biology – including detailed anatomy, regenerative capacities, and reproductive behavior – still require further investigation. Our knowledge of acoel life histories is limited to a small number of anatomical descriptions of adult specimens collected from the field. Characterizing the anatomy of a model acoel, understanding how its organs grow, scale and regenerate, and documenting its reproductive processes can reveal key elements of its natural history, uncover new biological phenomena and provide a basis for future research.
To address this, Chandra et al. employed modern imaging and behavioural techniques to study the life history of the three-banded panther worm, Hofstenia miamia. The researchers first examined the growth and regenerative dynamics of reproductive organs and found that the growth rate of these organs depends on the size of an individual, as well as active mechanisms that coordinate organ scaling. Next, using advanced labelling and imaging techniques, Chandra et al. characterised the reproductive anatomy at cellular resolution and identified structures previously undescribed. Finally, they investigated reproductive behaviour and discovered a new mode of egg-laying: H. miamia lays eggs through its mouth. The eggs are deposited in communal clutches, and individuals assess environmental conditions to decide whether – and when – to lay eggs, indicating a more complex neural control of reproductive activity.
Acoels offer valuable insights into early animal evolution and regenerative systems, with H. miamia emerging as an important model species. Chandra et al. have established key resources and foundational knowledge for systematic study of this species by elucidating core aspects of reproductive development, regeneration, and egg-laying behaviour. More broadly, these findings provide crucial anatomical and behavioural observations relevant to taxonomy, regenerative biology, evolutionary biology, and neuroscience.
