Recapitulating whipworm development in vitro using caecaloids

Whipworms (Trichuris spp.) are intracellular intestinal parasites that develop within the host caecal epithelium, yet the host signals that regulate their growth and developmental progression remain poorly understood. Progress in studying these processes has been limited by the lack of physiologically relevant in vitro systems capable of supporting sustained whipworm development. Here, we established an in vitro infection system using caecal organoids (caecaloids) and evaluated their capacity to support sustained growth and morphological development of Trichuris muris larvae. To rigorously validate this system, we generated a comprehensive and up-to-date anatomical and biometrical reference dataset describing the whole-body growth and tissue-level morphogenesis of T. muris throughout its life cycle in vivo. Quantitative analysis across larval and adult stages confirmed that the trajectory of parasite growth is largely conserved across host mouse strains and provided a detailed contextualised description of the development of key anatomical structures of T. muris. Using this reference framework, we evaluated parasite growth and development in long-term T. muris-caecaloid co-cultures. Larvae invading the caecaloid epithelium remained intracellular within syncytial tunnels and exhibited sustained growth over extended culture periods. in vitro parasites developed increasing anatomical complexity, including formation of the bacillary band, stichosome, intestine, and rectum. Importantly, quantitative comparisons revealed that larvae developing within caecaloids follow growth trajectories and morphological developmental patterns closely resembling those observed in vivo. This study therefore presents the first detailed anatomical and morphometric framework for validating whipworm development in an organoid system and provides concrete evidence that the caecaloid epithelium is sufficient to trigger and sustain whipworm growth and morphogenesis, establishing caecaloids as a powerful experimental platform for investigating Trichuris infection and development.