Adhesion of Crithidia fasciculata promotes a rapid change in developmental fate driven by cAMP signaling

Kinetoplastids are single-celled parasites responsible for human and animal disease. For the vast majority of kinetoplastids, colonization of an insect host is required for transmission. Stable attachment to insect tissues via the single flagellum coincides with differentiation and morphological changes. Although this process is essential for the generation of infectious forms, the molecular mechanism driving differentiation following adherence is not well understood. To study this process, we elaborate upon an in vitro model in which flagellated swimming cells of the kinetoplastid Crithidia fasciculata rapidly differentiate following adhesion to artificial substrates. Manipulation of culture parameters revealed that growth phase and time had a strong influence on the proportion of adherent cells. Live imaging of cells transitioning from swimming to an attached cell fate show parasites undergoing a defined sequence of events including an initial adhesion near the base of the flagellum, immediately followed by flagellar shortening, cell rounding, and the formation of a hemidesmosome-like structure between the tip of the shortened flagellum and the substrate. We have also assayed the role of the cyclic AMP (cAMP) signaling pathway in differentiation of C. fasciculata . Pharmacological inhibition of cAMP phosphodiesterases eliminated the ability of swimming cells to attach without affecting their growth rate. Further, treatment with inhibitor did not affect the growth rate of established attached cells, indicating its effect is limited to a critical window of time during the early stages of adhesion. Finally, in swimming parasites we have shown that a receptor adenylate cyclase localizes to the distal portion of the flagellum. In attached cells it is absent from the shortened flagellum and instead localizes to the cell body. Similarly, a putative phosphodiesterase, found along the length of the flagellum, also relocalizes to the cell body in attached parasites. These data suggest that in C. fasciculata cAMP signaling is required for adherence, that cAMP flux in the flagellum of swimming cells is spatially restricted, and that signaling domains may be reorganized during differentiation and attachment. These studies contribute to our understanding of the flagellum as a multi-functional organelle integrating processes related to motility, signaling, attachment, and differentiation and further develop C. fasciculata as a model kinetoplastid. Author Summary Parasites from the order Kinetoplastida are transmitted by insects and cause diseases such as Leishmaniasis, Chagas disease, and Human African Trypanosomiasis. A key aspect of the life cycle of these parasites is their ability to adhere to surfaces within the insect and subsequently differentiate into forms that are transmissable to their next host. Here, we explore the molecular mechanisms underpinning both adherence and differentiation using the mosquito parasite Crithidia fasciculata . This organism is closely related to pathogenic species but grows to high densities in culture and adheres robustly in vitro. We identified factors affecting the rate of adherence and defined morphological stages of this process including rapid shortening of the cell’s single flagellum. Using electron microscopy, we confirmed that adhesion to artificial substrates results in the formation of a filament-rich adhesive plaque at the tip of the flagellum that resembles the attachment to insect tissue. We also demonstrate the key role played by the cyclic AMP signaling pathway during adherence and differentiation. Specifically, pharmacological inhibition of enzymes that degrade cyclic AMP completely blocks adherence, and tagging of several proteins in this pathway show that their localization along the flagellum changes following differentiation to the attached form. These data provide insights into processes critical for all kinetoplastid life cycles. ### Competing Interest Statement The authors have declared no competing interest.