Timing and original features of flagellum assembly in trypanosomes during development in the tsetse fly

Abstract

AbstractTrypanosoma brucei exhibits a complex life cycle alternating between tsetse flies and mammalian hosts. When parasites infect the fly, cells differentiate to adapt to life in various tissues, which is accompanied by drastic morphological and biochemical modifications especially in the proventriculus. This key step represents a bottleneck for salivary gland infection. Here we monitored flagellum assembly in trypanosomes during differentiation from the trypomastigote to the epimastigote stage, i.e. when the nucleus migrates to the posterior end of the cell. Three-dimensional electron microscopy (Focused Ion Bean Scanning Electron Microscopy, FIB-SEM) and immunofluorescence assays provided structural and molecular evidence that the new flagellum is assembled while the nucleus migrates towards the posterior region of the body. Two major differences with well known procyclic cells are reported. First, growth of the new flagellum begins when the associated basal body is found in a posterior position relative to the mature one. Second, the new flagellum acquires its own flagellar pocket before rotating on the left side of the anterior-posterior axis. FIB-SEM revealed the presence of a structure connecting the new and mature flagellum and serial sectioning confirmed morphological similarities with the flagella connector of procyclic cells. We discuss potential function of the flagella connector in trypanosomes from the proventriculus. These findings show that T. brucei finely modulates its cytoskeletal components to generate highly variable morphologies.Author SummaryTrypanosoma brucei is a flagellated parasitic protist that causes human African trypanosomiasis, or sleeping sickness and that is transmitted by the bite of tsetse flies. The complex life cycle of T. brucei inside the tsetse digestive tract requires adaptation to specific organs and follow a strictly defined order. It is marked by morphological modifications in cell shape and size, as well organelle positioning. In the proventriculus of tsetse flies, T. brucei undergoes a unique asymmetric division leading to two very different daughter cells: one with a short and one with a long flagellum. This organelle is crucial for the trypanosome life cycle as it is involved in motility, adhesion and morphogenesis. Here we investigated flagellum assembly using molecular and 3D Electron Microscopy approaches revealing that flagellum construction in proventricular trypanosomes is concomitant with parasite differentiation. During flagellum growth, the new flagellum is connected to the mature one and rotates around the mature one after its emergence at the cell surface. The sequence of events is different from what is observed in the well-studied procyclic stage in culture revealing different processes governing morphological development. These results highlight the importance to study pathogen development in their natural environment.